REG - Sovereign Metals Ltd - Kasiya MRE Significantly Upgraded Ahead of DFS
Wed 07:00
For best results when printing this announcement, please click on link below:
https://newsfile.refinitiv.com/getnewsfile/v1/story?guid=urn:newsml:reuters.com:20260318:nRSR1176Xa&default-theme=true
RNS Number : 1176X Sovereign Metals Limited 18 March 2026
NEWS RELEASE I 18 MARCH 2026
KASIYA MINERAL RESOURCE ESTIMATE SIGNIFICANTLY UPGRADED AHEAD OF DFS
Measured & Indicated Resources Increase by 32% Cementing Kasiya as the
World's Largest Natural Rutile Deposit
KEY HIGHLIGHTS
· Total Rutile Mineral Resource increases to 2.1 billion tonnes at
0.96% rutile for 20.3Mt contained rutile with 0.95% TGC for 20.0Mt contained
graphite (M,I&I)
· Measured and Indicated (M&I) contained rutile surges 32% to
16.1Mt (1.6 billion tonnes at 0.98% rutile) - a material increase in resource
confidence ahead of DFS
· Measured Resource planned to be mined and processed in first six
years of operations - highest confidence JORC Code category, achieved at
Kasiya for the first time
· Resource upgrade delivers the classification standard required for
bankable DFS - a critical milestone on the path to project financing
Sovereign Metals Limited (ASX:SVM; AIM:SVML; OTCQX:SVMLF) (Sovereign or the
Company) is pleased to announce an updated Mineral Resource Estimate (MRE) for
its flagship Kasiya Rutile-Graphite Project (Kasiya or Project) in Malawi.
The updated MRE will serve as the resource base for the Kasiya Definitive
Feasibility Study (DFS) mine schedule, replacing the previous April 2023 MRE
(Previous MRE).
Combined Measured and Indicated rutile Resources have grown 38% to 1,652Mt,
now representing 77% of the total Resource base. This material improvement in
Resource confidence reflects the extensive infill drilling programs completed
and provides a robust foundation for the forthcoming DFS. Importantly, Kasiya
has achieved a Measured Resource for the first time, which represents at least
the first six years of planned operations.
Managing Director and CEO Frank Eagar commented:
"This updated MRE is a significant milestone for Sovereign as we advance
Kasiya through the Definitive Feasibility Study. The 32% increase in Measured
and Indicated contained rutile, together with our first-ever Measured
Resource, reflects both the quality of our geological dataset and the
exceptional nature of this deposit. The rigour of the updated resource
estimation gives our strategic and commercial partners and us high confidence
in the resource base underpinning our potential mine schedule. Kasiya remains
unmatched globally as a source of natural rutile, and this MRE update
reinforces its potential as a long-life, low-cost supplier to critical global
supply chains."
UPDATED MINERAL RESOURCE ESTIMATE
Table 1: Kasiya Rutile Mineral Resource Estimate (March 2026)
Class Tonnes Rutile Grade Rutile TGC TGC Rutile Eq.
(Mt) (%) (Mt) (%) (Mt) (%)
Measured 107 1.05 1.12 1.56 1.67 1.94
Indicated 1,545 0.97 14.99 1.05 16.26 1.57
Total M&I 1,652 0.98 16.12 1.09 17.93 1.60
Inferred 452 0.91 4.12 0.45 2.02 1.17
Total Rutile MRE 2,105 0.96 20.24 0.95 19.95 1.51
Note: Rutile Mineral Resource defined from a pit shell with mineralisation
defined as >= 0.75% Rut95 for the pit shell optimisation run. A rutile
concentrate net price of US$1,400 was used to determine economic value.
Graphite had no value for this run. The Rutile MRE is reported based on all
rutile mineralisation >=0.4% Rut95 within the optimised pit shell. Any
apparent differences in totals are due to rounding.
Table 2: MRE Comparison - Previous vs. Updated
Metric Previous MRE Updated MRE Change
Total Resource Tonnes (Mt) 1,809 2,105 +16%
Measured & Indicated Tonnes (Mt) 1,200 1,652 +38%
M&I Contained Rutile (Mt) 12.2 16.1 +32%
Total Contained Rutile (Mt) 17.9 20.2 +13%
Figure 1: Increase in Kasiya MRE across categories
The updated MRE provides the resource foundation for the upcoming DFS mine
schedule and mine optimisation study. The step-up in Measured and Indicated
resource confidence is a critical input for the DFS, enabling the Company to
present a resource base with the classification level required for bankable
project financing and offtake discussions.
Sovereign's DFS is progressing across all workstreams including mining,
processing, infrastructure, environmental and social studies, and commercial
arrangements.
MRE EMPHASISES SOVEREIGN'S STRATEGIC SIGNIFICANCE FOR GLOBAL SUPPLY CHAINS
Kasiya is a uniquely diversified source of critical minerals essential to
defence, industrial and energy security. The updated MRE demonstrates Kasiya's
potential to supply titanium-bearing rutile and graphite for several decades
and its position as the world's single most strategically important source of
rutile.
Natural rutile is a critical mineral essential to titanium metal production
for aerospace, defence and medical applications. According to leading titanium
consultants TZ Minerals International Pty Ltd (TZMI), demand for rutile from
the titanium metals industry is forecast to grow 3% annually, while global
supply is expected to decline by 7% per year over the next decade. The market
faces a widening structural deficit.
Natural rutile commands a significant premium over alternative titanium
feedstocks due to its superior grade (95%+ TiO₂), lower processing costs,
and smaller environmental footprint. With no meaningful domestic production in
key consuming nations, Kasiya's scale and quality position it as the single
most strategically important source of natural rutile outside of current
producing regions.
With the updated MRE, Kasiya is positioned to address this critical supply gap
at a time when new sources of natural rutile are urgently needed.
The graphite resource further enhances Kasiya's strategic value with a second
critical mineral. With graphite demand forecast to grow 9% annually across
battery and industrial applications (Benchmark Mineral Intelligence), the
Project's 20.0Mt contained graphite provides significant exposure to a
valuable by-product.
KASIYA MRE TECHNICAL DETAILS
The Kasiya MRE has been prepared by Sovereign under guidance by MSA Group and
is reported in accordance with the JORC Code (2012) (JORC).
Rutile mineralisation lies in laterally extensive, near-surface, flat
"blanket" style bodies in areas where the weathering profile is preserved and
not significantly eroded. The high-grade zones are relatively geologically
consistent with limited variability along and across strike. The
mineralisation style is illustrated best in Figure 2 below.
Figure 2: MRE with E-W Cross Sections 8,479,200N (A-B) and E-W Cross Sections
8,467,600N (C-D) (cross section are at +/- 100m with 30x vertical
exaggeration)
SUMMARY OF RESOURCE ESTIMATE REPORTING CRITERIA
As per ASX Listing Rule 5.8 and the JORC reporting guidelines, a summary of
the material information used to estimate the MRE is detailed below.
Geology
Regional Geology
The greater part of Malawi is underlain by crystalline Precambrian to lower
Palaeozoic rocks referred to as the Malawi Basement Complex. In some parts,
these rocks have been overlain unconformably by sedimentary and volcanic rocks
ranging in age from Permo-Triassic to Quaternary. The Basement complex has
undergone a prolonged structural and metamorphic history dominated by uplift
and faulting, resulting in the formation of the Malawi Rift Valley.
Kasiya is located on the Lilongwe Plain, which is underlain by the Basement
Complex paragneisses and orthogneisses, which are part of the Mozambique Belt.
The bulk of the gneisses are semi-pelitic, but there are bands of psammitic
and calcareous rocks that have been metamorphosed under high pressure and
temperature conditions to granulite facies.
Interspersed within the paragneiss units are lesser orthogneisses, often
cropping out as conspicuous tors, as well as amphibolites, pegmatites and
minor mafic to ultramafic intrusions. Foliation and banding in the gneisses
have a broad north-south strike over the general area. Thick residual soils
and pedolith with some alluvium overlie the gneisses and include sandy,
lateritic and dambo types.
Figure 3: Drone photo above the Kasiya Deposit showing the open, flat terrain
Project Geology
Sovereign's tenure covers 644 km(2) over an area to the north, west and south
of Malawi's capital city, covering the Lilongwe Plain. The topography is
generally flat to gently undulating, and the underlying geology is dominated
by paragneiss with pelitic, psammitic and calcareous units.
A particular paragneiss unit is rich in rutile and graphite and is the primary
source of both minerals in the area. This area was deeply weathered during the
Tertiary, and rutile concentrated in the upper part of the weathering profile,
forming residual placers, such as the Kasiya deposit. Once this material is
incised and eroded, it is transported and deposited into wide, regional
braided river systems, forming alluvial heavy mineral placers such as the Bua
Channel.
Kasiya Deposit Geology
The high-grade rutile deposit at Kasiya is best described as a residual
placer, or otherwise known as an eluvial heavy mineral deposit. It is formed
by weathering of the primary host rock and concentration in place of heavy
minerals, as opposed to the high-energy transport and concentration of heavy
minerals in a traditional placer.
The presence of abundant kyanite and graphite in the host material suggests a
meta-sedimentary protolith. The protolith likely started with a 0.5-1.5Ga
basin that also experienced a consistent influx of titanium minerals.
These sedimentary rocks were subject to granulite facies metamorphism under
reduced conditions in the Pan-African Orogeny. The metamorphic facies, reduced
environment, relatively high titanium content and low iron content resulted in
rutile being the most stable titanium mineral under these conditions. Slow
exhumation and cooling then resulted in re-crystallisation as paragneisses
containing coarse rutile and graphite.
The final and most important stage of rutile enrichment came as tropical
weathering during the Tertiary depleted the top ~8m of physically and
chemically mobile minerals. This caused significant volume loss and concurrent
concentration of heavy resistate minerals, including rutile and kyanite.
Rutile mineralisation therefore lies in laterally extensive, near-surface,
flat "blanket" style bodies in areas where the weathering profile is
preserved. The Kasiya deposit shows widespread, high-grade mineralisation
commonly grading 1.2% to 2.0% rutile in the top 3-5m from surface. Moderate
grade mineralisation, generally grading 0.5% to 1.2% rutile, commonly extends
from 5m to the base of the soft saprolite unit to typically 20-30m depth,
where it terminates on the hard saprock basement.
Graphite generally occurs in broad association with rutile. However, it is
depleted in the top 3-5m and therefore can often show an inverse grade
relationship with rutile in the near-surface zones. At depths generally
greater than 5m, graphite is not depleted, and rutile is not particularly
enriched, so a more consistent grade relationship exists.
Drilling Techniques
Spiral hand-auger (HA) drilling, Push-tube and/or diamond core (PTDD), and Air
core (AC) drilling methods have been used extensively at the Kasiya deposit by
Sovereign to define mineralisation and to obtain quantitative rutile and
graphite (TGC) assay information.
HA drilling was executed by Sovereign field teams using a manually operated
enclosed-flight Spiral Auger (SP / SOS) system produced by Dormer Engineering
in Queensland, Australia. The HA bits are 62mm and 75mm in diameter with 1m
long steel rods. Each 1m of drill advance is withdrawn and the contents of the
auger flight removed into bags and set aside. An additional 1m steel rod is
attached and the open hole is re-entered to drill the next metre. This is
repeated until the drill hole is terminated often due to the water table being
reached or due to bit refusal. The auger bits and flights are cleaned between
each metre of sampling to avoid contamination.
PTDD drilling is undertaken using a drop hammer Dando Terrier MK1 and a drop
hammer DL650 by Geo-consult and Thompsons Drilling. The drilling generated 1m
runs of 88mm PQ core in the first 2m and then transition to 61mm core for the
remainder of the hole. Core drilling is oriented vertically by spirit level.
Figure 4: Core drilling (push tube) in action at Kasiya
AC drilling was completed by Thompson Drilling utilising a Smith Capital 10R3H
compact track-mounted drill. The drilling is vertical and generates 1m samples
with care taken in the top metres to ensure good recoveries of the high-grade
surface material. The AC sample is collected by the on-board cyclone into
heavy-duty RC sample bags. Drilling continues until bit refusal onto basement
~20-30m. Sample bags are immediately transported back to Sovereign's field
laydown yard where they are processed. AC drilling is on a nominal 200m by
200m pattern.
The drilling programs to date show a surface mineralised extent, defined
nominally by a 0.7% rutile cut-off, of approximately 268.6 km(2) with numerous
areas of high-grade rutile and graphite defined.
The PTDD and AC twin and density sample holes are selectively placed
throughout the deposit to ensure a broad geographical and lithological
coverage for the analysis.
MSA has reviewed Standard Operating Procedures (SOPs) for HA, SA, PTDD and AC
drilling and found them to be fit for purpose and support the resource
classifications as applied to the MRE.
Figure 5: Air-core (AC) drilling at Kasiya in May 2022.
Sampling Techniques
HA samples are obtained at 1m intervals generating on average approximately
2.5kg of drill sample. HA samples are manually removed from the auger bit and
sample recovery is visually assessed in the field. As samples become wet at
the water table and recovery per metre declines, the drill hole is terminated.
Each 1m sample is sun dried, logged and weighed. HA samples are composited
based on regolith weathering boundaries defined by geology logging. Each 1m of
sample is dried, lightly pressed to remove soft aggregates and riffle-split to
generate a total sample weight of 3kg for analysis, generally at 2 - 5m
intervals. This primary sample is then riffle split again to provide a 1.5kg
sample each for rutile and graphite analyses.
SA samples are bulk spiral auger samples primarily designed to collect a large
sample for metallurgical and pilot plant testwork. Bit sizes range from 300 mm
to 700mm diameter. The samples are collected on 1m intervals, laid out on a
large tarpaulin to be sun dried before using a cone and quarter method (for
the 700mm diameter) to produce a roughly 100kg sample which is then riffle
split to produce a 3kg sample, with the file split providing 1.5 kg each for
rutile and graphite analysis. Samples are analysed in 1m intervals.
PTDD samples are predominantly from HQ sized core (61mm diameter). Half core
1m samples are sun dried, logged and weighed. Samples are then lightly pressed
and composited over 2m intervals. An equal mass is taken from each
contributing metre to generate a 1.5kg composite sample. Individual
recoveries of core samples are recorded on a quantitative basis. Core recovery
is very good overall at >95%.
AC samples are collected in 1m increments. AC samples are dried, riffle split,
lightly pressed and composited. Samples are collected and homogenised prior to
splitting to ensure sample representivity. ~1.5kg composite samples were
defined by the regolith boundaries in earlier drilling. More recent AC
drilling utilised regular 2m downhole composites. An equivalent mass is taken
from each primary sample to make up the composite.
During 2024 twin drilling campaigns, samples were processed at 1m intervals to
get a better understanding of drilling and deposit variability.
The sampling and compositing methods described are considered appropriate and
reliable based on accepted industry practice. MSA completed an on-site audit
of sampling and sample processing and deemed the processes fit for purpose.
Sample Analysis Methodology
All samples arrive at Sovereign's Malawi laboratory where they are sorted and
checked in. Graphite samples are identified and prepared for export, while the
equivalent rutile samples begin the sample workflow to generate the rutile
non-magnetic concentrate (NM) for export for TiO2 and multi-element XRF
analysis. Prior to June 2024 XRF analysis was completed at ALS Perth, Western
Australia, currently Scientific Services South Africa (SS) laboratory in Cape
Town, South Africa is being used. Umpire checks have shown good correlation
between the two external laboratories. Audit of Sovereign's laboratory
premises, staff, sample analysis and QA procedures was completed by MSA during
two site visits in 2024 and 2025.
SVM Malawi Laboratory Rutile Workflow
· Samples are dried in a commercial oven for 1 hour at 105℃ and a dry
raw samples mass is recorded.
· Samples are soaked in 1% Tetrasodium pyrophosphate (TSPP) solution
overnight and then lightly agitated prior to wet screening.
· Wet screening occurs at 5mm, 600µm and 45µm to remove oversize and
slimes (-45µm) material. Each +45µm retained fraction is dried, logged and
weighed.
· The resulting sand fraction +45µm -600mm is oven dried for 1 hour at
105℃ after which its dry weight is recorded.
· The sand fraction is then passed over a Gemeni wet shaking table at a
constant feed rate to generate a heavy mineral concentrate (HMC).
· Heavy Liquid Separation (HLS) at Diamantina Laboratories in Perth was
initially trialled as a preferred separation method but was quickly superseded
(supported by QA analysis) by wet-table separation on account of substantial
near-density gangue material reporting to the HM sink for the HLS technique.
The HLS analyses represent 6% of the MRE assay dataset.
· The wet-tabled HMC is then subject to magnetic separation @ 16,800G
(2.9Amps), producing a magnetic (Mag) and non-magnetic (NMag) fraction. The
separation is performed using a Mineral Technologies Reading Pilot IRM
(Induced Roll Magnetic) purchased by Sovereign and located at the Company's
laboratory in Malawi. Pre-2022, this step was completed by Allied Mineral
Laboratories Perth (AML) in Perth, Western Australia.
The Malawi onsite laboratory sample preparation methods are considered
quantitative to the point where the NMag concentrate (containing the rutile)
is produced. Several generations of QEMSCAN analysis of the NMag and Mag
fractions performed at ALS Metallurgy show dominantly clean and liberated
rutile grains and confirm that rutile is the only titanium species in the NMag
fraction.
Recovered rutile is defined and reported here as: TiO(2) recovered in the SAND
+45 to -600um range to the NMag concentrate fraction as a % of the total
primary, dry, raw sample mass divided by 95% (to represent an approximation of
final product specifications). i.e recoverable rutile within the whole sample.
Graphite Testwork
Once secured the 1.5kg graphite sample are delivered to Intertek Group plc
(Intertek) in Johannesburg, South Africa, 750g of each 1.5kg graphite sample
is pulverised to -75um with a 150g dissolved in dilute hydrochloric acid to
liberate carbonate carbon. The solution is filtered using a filter paper, and
the collected residue is then dried to 425°C in a muffle oven to drive off
organic carbon.
The 150g dried sample is transported to Perth, Australia where it is then
combusted in an Eltra CS-800 induction furnace infra-red CS analyser to yield
total graphitic or elemental carbon (TGC).
QAQC
Accuracy monitoring is achieved through submission of certified reference
materials (CRM's). Sovereign uses internal and externally sourced wet
screening reference material inserted into samples batches at a rate of 1 in
20.
SS, ALS and Intertek both use internal CRMs and duplicates on XRF and TGC
analyses. Sovereign also inserts its customised CRMs into all sample batches
at a rate of 1 in 20.
Analysis of sample duplicates is undertaken by standard statistical
methodologies (Scatter, Pair Difference and QQ Plots) to test for bias and to
ensure that sample splitting is representative. Standards determine assay
accuracy performance, monitored on control charts, where failure (beyond 2SD
from the accepted mean value of the standard) initiates investigation and may
trigger re-processing of the affected batch.
Examination of the QA/QC sample data indicates satisfactory performance of
field sampling protocols and assay laboratories providing acceptable levels of
precision and accuracy. Rutile determination by alternate methods showed no
material bias.
Estimation Methodology
Datamine Studio RM, LeapFrog and Supervisor software are used for the data
analysis, variography, geological interpretation and resource estimation.
A 3D block model honouring the geology boundaries which included weathering
horizons; barren mafic intrusives; surface clay horizons and presence of
barren or low grade amphibolite was created. The model was also coded with the
tenement EL codes, rock in-situ dry bulk density and moisture content.
Rutile mineralisation was defined as the last intercept >=2m down hole
exceeding 0.4% rutile. Generally, rutile grade is highest at the surface
gradually reducing in grade with depth. Using this guideline very little
internal low grade/waste is introduced. The resulting sample point data was
used to create the bounding lower surface digital terrane model (DTM) for a
rutile mineralisation, topography DTM is the upper surface. Additional manual
points were interpreted section by section to ensure consistency especially in
areas with wider spaced drilling.
Graphite mineralisation was defined as the highest up hole intercept >=2m
exceeding 0.6% TGC. Generally TGC grade is highest at depth gradually reducing
in grade closer to the surface. Using this guideline very little internal low
grade/waste is introduced. A graphite mineralisation upper limit DTM was
constructed following a similar process to that used for the Rutile DTM. The
lower limit of graphite mineralisation was either the base of drilling or the
top of SAPR if drilling intersected SAPR.
Eight grade domains were created, 4 mineralised and 4 low grade / waste for
both rutile and graphite. The domains are derived from the combination of
weathering type inside or outside the mineralisation DTM's. Samples were
composited to 1 sample per drillhole per domain. Rutile and TGC samples were
treated independently as there is no correlation between rutile and TGC
grades.
The composite populations generally approximated normal distributions with
some -ve and/or +ve skewness relating to the imposed mineralisation boundary.
Ordinary Kriging (OK) was considered the best grade estimator for both rutile
and graphite due to the near normal grade populations and adequate variograms.
Variography analysis was used to determine domain nugget effect and OK search
and neighbourhood parameters.
Each grade domain was treated as a 2D seam and estimated using OK with dynamic
anisotropy which followed the broad mineralisation continuity trends. No
declustering or removal of twin data was required, as OK is an efficient
declustering algorithm, and the post OK checks demonstrated no negative
weights in the mineralised zones. Any areas not estimated were set to waste
grades.
The parent cell size used is equivalent to the average drill hole spacing
within the Indicated Resource (200m*200m). XY sub-celling to 50m*50m is
adequate resolution for horizontal boundaries. Seam modelling ensured the
mineralisation, weathering and topography layers were vertically accurate
(within the 50m horizontal resolution). Grade was estimated using the parent
cell panel size.
Grade estimation was constrained by hard boundaries (domains) that result from
the geological interpretation and mineralisation interpretation.
Top Capping was applied to the composites considered to be outliers to reduce
local high grade bias. Generally <1% of samples had a grade cap applied.
Validation of the grade estimate was completed both visually and
statistically. Visual validation by loading the model and drill hole files and
annotating, colouring and using filtering to check for the appropriateness of
the estimate. Distributions of section line averages (swath plots) for drill
holes and models were prepared for each zone and orientation for comparison
purposes.
The resource model has appropriately averaged the informing drill hole data
and is considered suitable to support the resource classifications applied to
the estimate.
In-situ dry bulk density was calculated from 400 core samples taken from
geographically and lithologically representative sites across the deposit. Dry
bulk density is calculated from PT drill core using a cylinder volume wet and
dry method performed by Sovereign in Malawi. Shelby tube core samples
collected from the 2024 PTDD drill program were analysed by CIVILAB in South
Africa.
Bulk density data was coded by weathering horizon. Population distributions
were then reviewed and obvious outlies removed. Either the mean or median were
used as the average for each weathering and/or rock type domain.
The average in-situ dry bulk density of the total MRE is 1.60 t/m3. This is
derived from using an average density of 1.39 t/m3 for the SOIL; 1.58 t/m3 for
the FERP, 1.66 t/m3 for the MOTT; 1.68 t/m3 for the PSAP; and 1.77 t/m3 for
SAPL. (Definitions provided in Appendix 1 below).
Mining and Metallurgy Factors
Dry-mining has been determined as the optimal method of mining for the Kasiya
Rutile deposit. The materials competence is loose, soft, fine and friable with
no cemented sand or dense clay layers, allowing for a free dig mining method.
It is considered that the strip ratio would be zero or near zero. Dilution is
minimal as rutile mineralisation occurs from surface and mineralisation is
generally gradational with few sharp boundaries.
Recovery parameters have not been factored into the estimate. However, the
valuable minerals are readily separable due to their density differential and
flotation characteristics and are expected to have high recoveries through the
proposed conventional wet concentration plant for rutile and flotation for
graphite, as demonstrated by metallurgical test work. Graphite losses occur
predominantly in the desliming and wet gravity circuit, with flotation
recoveries above 95% in variability testing.
Sovereign has announced three sets of metallurgical results to the market (24
June 2019, 9 September 2020 and 7 December 2021), relating to the Company's
ability to produce a high-grade rutile product with a high recovery via simple
conventional processing methods. Subsequent to this Sovereign has reported
results related to metallurgical testwork within the following market
announcements:
· "Kasiya Scoping Study Confirms Globally Significant Natural Rutile
Project" dated 16 December 2021;
· "Kasiya Expanded Scoping Study Results" dated 16 June 2022; and
· "Kasiya Pre-Feasibility Study Results" dated 28 September 2023.
Sovereign engaged AML to conduct the metallurgical test work on the rutile
circuit inclusive of the ongoing DFS to provide input for metallurgy and
engineering process design. The work has consistently shown a premium quality
rutile product of 95.0%+ TiO(2) with low impurities could be produced with
recoveries of up to 98% and with favourable product sizing.
Sovereign has also received third-party confirmations for the quality of its
rutile product, including validation from one of Japan's premier titanium
metal (sponge and ingot) producers, Toho Titanium Company Limited (Toho). Toho
has confirmed the suitability of natural rutile from Kasiya for manufacturing
high-specification titanium products.
Gravity separation was effective at concentrating graphite to a "light mineral
pre-concentrate" due to its low specific gravity (~2.2 t/m³), providing an
upgrade of graphite grade to the flotation circuit to about three times the
run-of-mine grade.
The "light tailings" from processing the 45-600 micron ore to generate the
rutile-enriched HMC is combined with "light tailings" from wet table gravity
processing the 600 micron to 1mm size fraction of the ore to maximise coarse
graphite recovery.
Graphite testwork programs were conducted at SGS Canada - Lakefield, ALS
Limited, and Core Resources Pty Ltd in Australia at benchtop and pilot scales,
including variability testwork, with pilot-scale programs supported by rougher
flotation at Maelgwyn Mineral Services Africa (Pty) Ltd in South Africa to
reduce shipment masses. A conventional graphite flotation and milling
flowsheet was used, except for no milling prior to rougher flotation.
Classification
The Kasiya MRE has been classified as Measured, Indicated or Inferred.
JORC classification considered geological understanding; mineralisation
continuity; drilling and sampling quality and spacing; OK estimation
efficiency (KE) and confidence (SoR); with consideration of the proposed
mining method and scale.
The dominant control on grade distribution within the mineralised zone is
intensity of weathering. Rutile is a mineral resistant to weathering and is
concentrated by depletion of less resistant minerals during the weathering
process resulting in higher grades near the surface where more intense
weathering has taken place. The weathering profiles are consistent and readily
defined by logging of drill samples.
Both rutile and graphite mineralisation have been well defined by drilling
with appropriate sample analysis to determine recovered rutile in-situ grade
and in-situ TGC. Both mineralisation zones are broad and continuous with
rutile dominant in the Soil, FERP and MOTT horizons, and graphite in the MOTT,
PSAP and SAPL horizons. There is significant overlap of the two mineralisation
zones. The mineralisation is truncated either by changes in the protolith or
displaced by mafic intrusives. Recent drainage has also impacted
mineralisation continuity. Minor near surface clay lenses and metamorphic
'pegmatitic' zones also displace mineralisation. These very minor internal
'waste' zones are readily visually identifiable during mining (as seen during
the 2024 trial mining exercise) and can be selectively either mined or
bypassed. The dominant zones of mineralisation exceed 10km of strike
continuity and range from 1 to 4 km in width.
Regional exploration was completed on a nominal 800m square grid, with infill
to 400m followed by either 200m square or 200m offset grid. Twin holes plus
some close spaced geostatistical drilling, close spaced channel sampling
during the trial mining and open pit sampling have all demonstrated the
robustness of the geology interpretation and mineralisation continuity.
KE generally exceeds 0.6 with SoR exceeding 0.85 in the appropriately drilled
mineralised zones.
On the basis of the high confidence geology interpretation; mineralisation
scale and continuity including taking into account the bulk mining method; and
very tight grade distributions within the estimation domains, the Competent
Person is comfortable classifying all of the rutile and graphite
mineralisation which lies above the base of drilling as either Measured,
Indicated or Inferred.
Measured was defined using a nominal KE >=0.7 to 0.75 and a SOR >=0.9,
which generally matches areas with a drill spacing closer than 200m. A
boundary was used to define the Measured Mineral Resource. At Kingfisher south
of 8,467,700N, infill drilling was only completed to the base of FERP (to
support minimum 5 year mine plan), so Measured was assigned to Soil+FERP and
Indicated to material below FERP.
Indicated was defined using a nominal KE >=0.4 to 0.5 and a SOR >=0.8,
which generally matches areas with a nominal drill spacing of 200 to 400m. A
boundary was used to define the Indicated Mineral Resource. All mineralisation
outside the Indicated boundary was classed as Inferred Mineral Resource.
The parameters used to define Indicated classification are different from the
previous MRE. The changes are primarily due to the improved grade modelling
methodology, which is based on treating each mineralisation domain as a single
2D seam model. This method supports the bulk dry mining process and improves
the grade confidence at wider drill spacings, as no selective mining is
anticipated within each seam.
The MRE was constrained to a potentially economic open pit shells to reflect
the JORC Code requirement for Reasonable Prospects for Eventual Economic
Extraction (RPEEE). The shell was defined using Whittle Open Pit Optimisation
with the following parameters:
Rutile: Net concentrate revenue US$1,400/t; Process recovery 97.6%;
Graphite: Net revenue US$1,200/t ; Process recovery 70.4%s;
Mining OPEX US$1.35/t; Process OPEX US$5.44/t.
The MRE is presented in three tables (see Tables 3-5).
Sensitivity options were run on graphite basket price from US$1,200/t to
US$2,000/t - the MRE is not sensitive to graphite price.
Cuf-off grades
All results reported are of a length-weighted average of in-situ grades.
A nominal bottom cut of 0.7% rutile is used, based on preliminary assessment
of resource product value and anticipated cost of operations.
MRE TABLES
Table 3: Kasiya March 2026 Model - Rutile Mineral Resource
Table 3 presents the rutile dominant mineral resource based on a higher rutile
cut-off pit shell - optimised using the $1,400 rutile price using a
mineralisation cutoff of 0.75% rutile. All material with a rutile grade
>=0.4% (the nominal mining breakeven grade) within the pit shell was
reported. This pit shell was generated to maximise high grade rutile as a
direct comparison with the previously reported MRE. The pit shell includes a
small proportion of internal waste <0.4% rutile which is shown in the
tabulation.
Category Class Tonnes Rutile Grade Rutile TGC TGC Rutile Eq.
(Mt) (%) (Mt) (%) (Mt) (%)
Rutile Mineralisation Measured 107 1.05 1.12 1.56 1.67 1.94
>=0.4% Rut95
Indicated 1,545 0.97 14.99 1.05 16.26 1.57
Inferred 452 0.91 4.12 0.45 2.02 1.17
Total Rutile MRE 2,105 0.96 20.24 0.95 19.95 1.51
Internal Waste Measured 1 0.24 0 1.88 0.02 1.32
Indicated 40 0.25 0.10 1.92 0.77 1.35
Inferred 7 0.22 0.02 1.69 0.12 1.19
Total internal waste in RPEEE 48 0.24 0.12 1.88 0.91 1.32
Total Rutile in Pit Shell 2,153 0.95 20.35 0.97 20.86 1.50
Note: Rutile Mineral Resource defined from an optimised pit shell with
mineralisation defined as >= 0.75% Rut95. A rutile concentrate net price of
US$1,400 was used to determine economic value. Graphite had no value for this
run.
Table 4: Kasiya March 2026 Model - Graphite Mineral Resource
Table 4 presents the remaining mineral resource within the primary pit shell
but outside (mainly below) the rutile-dominant pit shell. This table is
further subdivided to show the high-grade graphite material >=0.6% TGC
(primarily at depth) and the lower-grade rutile material (primarily at the
edges of the deposit). The 0.6% TGC cut-off was selected as the statistically
'natural' value separating higher grade from lower grade.
Category Class Tonnes TGC TGC Rutile Grade Rutile Rutile Eq. Dry BD
(Mt) (%) (Mt) (%) (Mt) (%)
TGC>=0.6% Measured 30 1.99 0.59 0.52 0.15 1.67 1.74
Indicated 629 1.86 11.69 0.4 2.53 1.47 1.69
Inferred 201 1.7 3.42 0.3 0.61 1.28 1.7
Subtotal HG 860 1.83 15.7 0.38 3.29 1.43 1.69
TGC<0.6% Measured 0.6 0.23 0 0.68 0 0.81 1.66
Indicated 195 0.23 0.45 0.65 1.27 0.78 1.6
Inferred 220 0.15 0.33 0.65 1.42 0.73 1.57
Subtotal MG 415 0.19 0.78 0.65 2.69 0.76 1.59
Total Graphite MRE 1,275 1.29 16.48 0.47 5.98 1.21 1.66
Note: Graphite Mineral Resource is all material inside the total MRE pit shell
after depletion of the Rutile Mineral Resource.
Table 5: Kasiya Combined Rutile-Graphite Mineral Resource Estimate within the
RPEEE pit shell (March 2026)
Table 5 presents the entire MRE constrained to the combined rutile and TGC
RPEEE Open Pit shell. No cutoff is applied.
Class Tonnes Rutile Grade Rutile TGC TGC Rutile Eq. Dry BD
(Mt) (%) (Mt) (%) (Mt) (%)
Measured 139 0.93 1.3 1.65 2.3 1.87 1.67
Indicated 2,409 0.78 18.9 1.21 29.2 1.48 1.62
Inferred 881 0.70 6.2 0.67 5.9 1.08 1.59
Total 3,428 0.77 26.3 1.09 37.3 1.39 1.62
Note: The Total MRE includes all rutile and graphite mineralisation within an
optimised open pit shell using a 95%+TiO(2) rutile (Rut95) concentrate revenue
price of net US$1,400/t and a Graphite product price of net US$1,200/t; Mine
OPEX US$1.35/t; Process OPEX US$5.44/t; Rutile recovery of 97.6%; Average
Graphite recovery of 70.4%. Figures are rounded and may not sum exactly.
Figures 6 & 7: Kasiya March 2026 Model - Rutile (Rut94) Mineral Resource
and Kasiya March 2026 Model - Graphite Mineral Resource
Enquiries
Frank Eagar, Managing Director & CEO
South Africa / Malawi
+27 21 140 3190
Sapan Ghai, CCO
London
+44 207 478 3900
Nominated Adviser on AIM and Joint Broker
SP Angel Corporate Finance LLP +44 20 3470 0470
Ewan Leggat
Charlie Bouverat
Joint Broker
Stifel +44 20 7710 7600
Varun Talwar
Ashton Clanfield
Forward Looking Statement
This release may include forward-looking statements, which may be identified
by words such as "expects", "anticipates", "believes", "projects", "plans",
and similar expressions. These forward-looking statements are based on
Sovereign's expectations and beliefs concerning future events. Forward looking
statements are necessarily subject to risks, uncertainties and other factors,
many of which are outside the control of Sovereign, which could cause actual
results to differ materially from such statements. There can be no assurance
that forward-looking statements will prove to be correct. Sovereign makes no
undertaking to subsequently update or revise the forward-looking statements
made in this release, to reflect the circumstances or events after the date of
that release.
Competent Persons Statement
The information in this announcement that relates to the Mineral Resources
Estimate is based on, and fairly represents, information compiled by Mr Jeremy
Witley, a Competent Person, who is a member of the South African Council for
Natural Scientific Professions (SACNASP Pr. Sci. Nat.), a Recognised
Professional Organisation' included in a list promulgated by ASX from time to
time. Mr Witley is a principal of MSA Group, an independent consulting
company. Mr Witley has sufficient experience, which is relevant to the style
of mineralisation and type of deposit under consideration, and to the activity
he is undertaking, to qualify as a Competent Person as defined in the 2012
Edition of the 'Australasian Code for Reporting of Exploration Results,
Mineral Resources and Ore Reserves' (and as a Qualified Person under the AIM
Rules). Mr Witley consents to the inclusion of the matters based on his
information in the form and context in which it appears.
The information in this announcement that relates to Exploration Results is
based on, and fairly represents, information compiled by Mr Malcolm Titley, a
Competent Person who is a member of The Australasian Institute of Mining and
Metallurgy and member of Australian Institute of Geoscientists. Mr Titley is
the Technical Services Manager of Sovereign and is a holder of unlisted
performance rights in Sovereign. Mr Titley has sufficient experience that is
relevant to the style of mineralisation and type of deposit under
consideration and to the activity being undertaken, to qualify as a Competent
Person as defined in the 2012 Edition of the 'Australasian Code for Reporting
of Exploration Results, Mineral Resources and Ore Reserves' (and as a
Qualified Person under the AIM Rules). Mr Titley consents to the inclusion in
the report of the matters based on his information in the form and context in
which it appears.
The information in this announcement that relates to Production Targets,
Processing, Infrastructure and Capital and Operating Costs is extracted from
an announcement dated 22 January 2025, which is available to view at
www.sovereignmetals.com.au. Sovereign confirms that: a) it is not aware of any
new information or data that materially affects the information included in
the original announcement; b) all material assumptions and technical
parameters underpinning the Production Target, and related forecast financial
information derived from the Production Target included in the original
announcement continue to apply and have not materially changed; and c) the
form and context in which the relevant Competent Persons' findings are
presented in this presentation have not been materially modified from the
original announcement.
The information contained within this announcement is deemed by the Company to
constitute inside information as stipulated under the Market Abuse Regulations
(EU) No. 596/2014 as it forms part of UK domestic law by virtue of the
European Union (Withdrawal) Act 2018 ('MAR'). Upon the publication of this
announcement via Regulatory Information Service ('RIS'), this inside
information is now considered to be in the public domain.
To view this announcement in full, including all images, tables and figures,
please refer to
https://api.investi.com.au/api/announcements/svm/1e1ba7f3-168.pdf
(https://api.investi.com.au/api/announcements/svm/1e1ba7f3-168.pdf) .
(https://api.investi.com.au/api/announcements/svm/1e1ba7f3-168.pdf)
Glossary
Abbreviation Description
°C Degrees Celsius
µm Micrometre or Micron
AACE American Association of Cost Engineering
AC Air-core
ALS ALS Metallurgical Laboratory
AML Allied Mineral Laboratories Perth
amsl Above Mean Sea Level
ARD Acid Rock Drainage
AS Australian Standard
ASNZS Australian and New Zealand Standard
ASX Australian Stock Exchange
AUD Australian Dollar
ave Average
BCM Bulk Cubic Meter
BOO Build Own Operate
Capex Capital Expenditure
CFR Cost and Freight
CEAR Central East African Railways
cm Centimetre
CPR Competent Persons Report
CRM Certified Reference Material
CSR Corporate Social Responsibility
d Day
D Discharge
d/y Days Per Year
DAP Delivered at Place
dB Decibel
DD Diamond-core Drilling
DFS Definitive Feasibility Study
DL Detection Limit
dmt Dry Metric Tonne
DRA DRA Limited
DTM Digital Terrane Model
EAD Environmental Affairs Department (of Malawi)
EAP Employee Assistance Program
EBITDA Earnings Before Interest, Taxes, Depreciation And Amortisation
EHS Environment, Health, And Safety
EIA Environmental Impact Assessment
EL Exploration Licence
EMP Environmental Management Plan
EPC Engineering, Procurement, Construction
EPCM Engineering, Procurement & Construction Management
ERP Emergency Response Plan
ESIA Environmental And Social Impact Assessment
ESR Environmental Scoping Report
FEED Front End Engineering And Design
FEL Front End Loader
FOB Free on Board
FS Feasibility Study
G&A General & Administration
GEL Generally Expected Levels
GHG Greenhouse Gas(es)
GISTM Global Industry Standards on Tailings Management
h Hour
h/d Hours Per Day
h/y Hours Per Year
HA Hand-auger
ha Hectare
HLS Heavy Liquid Separation
HMC Heavy Mineral Concentrate
HR Human Resources
HRMP Human Resources Management Plan
HSE Health, Safety and Environment
HSEMS Health Safety and Environmental Management System
HSMP Health and Safety Management Plan
HV High Voltage
IBC Intermediate Bulk Container
ICP-MS Inductively Coupled Plasma Mass Spectrometer
ICP-OES Inductively Coupled Plasma Optical Emission Spectrometry
ID Internal Diameter
IDW Inverse-Distance Weighted Algorithm
IFC International Finance Corporation
IRR Internal Rate of Return
IT Information Technology
IUCN International Union for Conservation of Nature
IVI Important Value Index
J Joule (Energy)
JECFA Joint FAO/WHO Expert Committee on Food Additive
JHA Job Hazard Analysis
JORC Australasian Joint Ore Reserves Committee
k Kilo or Thousand
kg Kilogram
km Kilometre
KPI Key Performance Indicator
KRW Korean Won
kt Kilo Tonne (Thousand Metric Tonne)
kW Kilowatt (Power)
kWh Kilowatt Hour
L Litre
LCT Locked Cycle Testwork
LME London Metals Exchange
LoM Life of Mine
LSE London Stock Exchange
LTI Lost Time Injury
LV Low Voltage
m Metre
M Million
m(2) Square Metre
m(3) Cubic Metre
Ma Mega annum (million years)
MAG Magnetic
MCC Motor Control Centre
MG Mine Gate
ML Metal Leaching
mm Millimetre
MNREM Ministry of Natural Resources, Energy and Mining
MPA Maximum Potential Acidity
MPN Most Probably Number (Count of Coliforms and E. coli)
MRA Malawi Revenue Authority
MRE Mineral Resource Estimate
mRL Metre Reduced Level
MRMR Mining Rock Mass Rating
Msal Meters Above Sea Level
MSDS Material Safety Data Sheet
Mt Million Tonnes (Metric)
Mt/y Million Tonnes Per Year
MTI Medical Treatment Injury
MTO Material Take-Off
MW Megawatt
N/A Not Applicable
NA Not Available
NAF Non-Acid Forming
NAG Net Acid Generation
NAPP Net Acid Producing Potential
ND Not Detected
NMAG Non-Magnetic
NOH&SC National Occupational Health and Safety Commission (Australia)
NPI Non Process Infrastructure
NPV Net Present Value
NR Not Regulated
NT Near Threatened
NTU Normalised Turbidity Unit
OHS&E Occupational Health, Safety & Environment
OK Ordinary Kriging
PEA Preliminary Economic Assessment
PFD Process Flow Diagram
PFS Pre-Feasibility Study
PPE Personal Protective Equipment
PS Performance Standard
PSU Practical Salinity Unit
PTDD Push-tube and/or diamond core
PWTP Potable Water Treatment Plant
QA/QC Quality Assurance And Quality Control
RAP Resettlement Action Plan
ROM Run-Of-Mine
RPEEE Reasonable Prospects for Eventual Economic Extraction
RRT Resource Rent Tax
s Second
SG Specific Gravity
SGS SGS Metallurgical Laboratory
SO2 Sulphur Dioxide
SOP Standard Operating Procedure
ST Total Sulphur
SVM Sovereign Metals Limited
t Tonne (Metric)
t/h Tonnes Per Hour
t/m3 Tonnes Per Cubic Metre
t/y Tonnes Per Year
ta Comminution Test Parameter
TARP Trigger, Action, Responsibility, Procedure
TBC To Be Confirmed
TC Total Carbon
TC Treatment Charge
TDS Total Dissolved Solids
TGC Total Graphitic Carbon
TSF Tailings Storage Facility
TSP Total Suspended Particulates
TSPP Tetrasodium Pyrophosphate
TSS Total Suspended Solids
TZMI TZ Minerals International Pty Ltd
UFD Utility Flow Diagram
UOM Unit of Measure
URTI Upper Respiratory Tract Infection
US EPA The United States Environmental Protection Agency
US$ United States Dollar
USD United States Dollar
UTM Universal Transverse Mercator
V Volt
VAT Value Added Tax
VSD Variable Speed Drive
VTEM Versatile Time Domain Electromagnetic
VU Vulnerable
w/v Weight/Volume
w/w Weight/Weight
WBG World Bank Group
WBS Work Breakdown Schedule
WHO World Health Organization
XRD X-Ray Diffraction
XRF X-Ray Fluorescence
APPENDIX 1: JORC CODE, 2012 EDITION - TABLE 1
Section 1 - Sampling Techniques and Data
Criteria JORC Code explanation Commentary
Sampling Techniques Nature and quality of sampling (e.g. cut channels, random chips, or specific Hand Auger (HA) samples are composited based on regolith boundaries and sample
specialised industry standard measurement tools appropriate to the minerals chemistry generated by hand-held XRF (pXRF). Each 1m of sample is dried and
under investigation, such as down hole gamma sondes, or handheld XRF riffle-split to generate a total sample weight of 3kg for analysis, generally
instruments, etc). These examples should not be taken as limiting the broad at 2 - 5m intervals.
meaning of sampling.
Spiral Auger (SA) samples are mechanical auger bulk samples collected at 1m
intervals. Each 1m of sample is dried and riffle-split to generate a total
sample weight of 3kg for analysis.
Push-Tube and/or Diamond Core (PTDD) core drilling is sampled routinely at 2m
intervals by compositing dried and riffle-split half core. Several PTDD holes
were sampled on 1m intervals in a twinning campaign with HA and AC.
Air-Core (AC) samples are generally composited on 2m intervals. Each 1m of
sample is dried and riffle-split to generate a total sample weight of 3kg for
analysis.
For all sampling methods the primary sample (nominally 3kg) is split to
provide two 1.5kg samples for both rutile and graphite analyses.
Include reference to measures taken to ensure sample representivity and the Drilling and sampling activities are supervised by a suitably qualified
appropriate calibration of any measurement tools or systems used. company geologist who is present at all times. All drill samples are
geologically logged by the geologist at the drill site/core yard.
Each sample is sun dried and homogenised. Sub-samples are carefully riffle
split to ensure representivity. The 1.5kg composite samples are then
processed.
An equivalent mass is taken from each sample to make up the composite. A
calibration schedule is in place for laboratory scales, sieves and field XRF
equipment.
Prior to June 2024 Placer Consulting Pty Ltd (Placer), then post June2024 MSA
Group Resource Geologists completed site visits and reviewed Standard
Operating Procedures (SOPs) for the collection and processing of drill samples
and found them to be fit for purpose and support the resource classifications
as applied to the MRE. The primary composite sample is considered
representative for this style of rutile and graphite mineralisation.
Aspects of the determination of mineralisation that are Material to the Public Logged mineralogy percentages, lithology/regolith information and TiO2%
Report. In cases where 'industry standard' work has been done this would be obtained from pXRF are used to assist in determining compositing intervals.
relatively simple (e.g. 'reverse circulation drilling was used to obtain 1 m Care is taken to ensure that only samples with similar geological
samples from which 3 kg was pulverised to produce a 30 g charge for fire characteristics are composited together.
assay'). In other cases more explanation may be required, such as where there
is coarse gold that has inherent sampling problems. Unusual commodities or
mineralisation types (e.g. submarine nodules) may warrant disclosure of
detailed information.
Drilling Techniques Drill type (e.g. core, reverse circulation, open‐hole hammer, rotary air Several sampling methods have been tested at Kasiya. The drill types deemed
blast, auger, Bangka, sonic, etc) and details (e.g. core diameter, triple or suitable for use in the MRE are Hand Auger (HA 62mm), Air Core (AC 75 and
standard tube, depth of diamond tails, face‐sampling bit or other type, 115mm), Push Tube and/or Diamond Core (PTDD 61 and 88mm) and Spiral Mechanical
whether core is oriented and if so, by what method, etc). Auger (SA 300 and 700mm).
Other sampling methods used for geological and verification purposes included
open pit bulk samples (PIT 1x1m), Channel samples (CH 62 and 100mm) from bulk
sample pits, the trial mining open pit and rehabilitation trial pits.
All sampling was carried out vertically to best intersect the horizontal
weathering and grade layers.
All material of interest is in the weathered zones located above the saprock
boundary, so no collection of oriented core was possible or warrented.
Two similar designs of HA drilling equipment are employed. HA drilling with
75mm diameter enclosed spiral bits (SOS) with 1m long steel rods and with 62mm
diameter open spiral bits (SP) with 1m long steel rods. The SP bit accounts
for less than 10% of the HA drilling, as the enclosed spiral proved to be the
more effective tool. Drilling is oriented vertically by eye.
Each 1m of drill sample is collected into separate sample bags and set aside.
The auger bits and flights are cleaned between each metre of sampling to avoid
contamination.
Core-drilling is undertaken using a drop hammer, Dando Terrier MK1. The
drilling generated 1m runs of 88mm PQ core in the first 2m and then
transitioned to 61mm core for the remainder of the hole. Core drilling is
oriented vertically by spirit level.
AC drilling was completed by Thompson Drilling utilising a Smith Capital 10R3H
compact track-mounted drill.
Each 1m sample bag is immediately transported back to Sovereign's secure field
laydown yard for processing.
Drill Sample Recovery Method of recording and assessing core and chip sample recoveries and results Samples are assessed visually for recoveries. The configuration of drilling
assessed. and nature of materials encountered results in negligible sample loss or
contamination.
HA and PT drilling is ceased when recoveries become poor once the water table
has been reached. Water table and recovery information is included in
lithological logs.
Core drilling samples are actively assessed by the driller and geologist
onsite for recoveries and contamination.
AC drilling recovery in the top few metres is moderate to good. Extra care is
taken to maximise sample recovery in these metres. Sample weight is recorded
to determine recovery at the rig at the time of drilling by the geologist.
Drilling is ceased when recoveries become poor or once Saprock or refusal has
been reached.
The use of the AC 115mm has been adopted as the standard since October 2025.
Improvements in both air pressure and cyclone management have resulted in
excellent recovery. This has been combined with the use of SA 300mm twin
drilling to the base of the FERP layer (4 to 6m) to further validate the
quality of the AC 115mm drilling.
Measures taken to maximise sample recovery and ensure representative nature of The Company's trained geologists supervise drilling on a 1 team 1 geologist
the samples. basis and are responsible for monitoring all aspects of the drilling and
sampling process.
For PT drilling, core is extruded into core trays; slough is actively removed
by the driller at the drilling rig and core recovery and quality is recorded
by the geologist.
AC samples are recovered in large plastic bags. The bags are clearly labelled
and delivered back to sovereign's laydown yard at the end of shift for
processing. Since October 2025 the cyclone is checked every 1m. If there is
any hang-up in the cyclone, this material is collected and recombined with the
primary sample.
Whether a relationship exists between sample recovery and grade and whether No relationship is believed to exist between grade and sample recovery. The
sample bias may have occurred due to preferential loss/gain of fine/coarse high percentage of silt and absence of hydraulic inflow from groundwater at
material. this deposit results in a sample size that is well within the expected size
range.
An oversize (>5mm) bias can occur where larger coarse fragments,
predominantly near the surface, appear preferentially recovered when using
different diameter drilling methods. The use of larger diameter drilling (AC
115mm and SA 300mm) negates the potential for this bias.
Logging Whether core and chip samples have been geologically and geotechnically logged Geological data is collected in adequate detail for use in Mineral Resource
to a level of detail to support appropriate Mineral Resource estimation mining estimation.
studies and metallurgical studies.
All individual 1m HA intervals are geologically logged, recording relevant
data using company codes. A small representative sample is collected for each
1m interval and placed in chip trays for future reference.
All individual 1m PT core intervals are geologically logged, recording
relevant data using company codes.
Half core remains in the trays and is securely stored in the company
warehouse.
AC and SA 1m intervals are geologically logged using company codes. A small
representative sample is collected for each 1m interval and placed in chip
trays for future reference.
Whether logging is qualitative or quantitative in nature. Core (or costean, All logging includes lithological features and estimates of basic mineralogy.
channel, etc.) photography. Logging is qualitative.
The PTDD core is photographed dry.
The total length and percentage of the relevant intersection logged 100% of samples are geologically logged.
Sub- sampling techniques and sample preparation If core, whether cut or sawn and whether quarter, half or all core taken. Due to the soft weathered nature of the material, core samples are carefully
cut in half using hand tools.
If non-core, whether riffled, tube sampled, rotary split, etc. and whether HA, PTDD, SA and AC hole samples are dried, riffle split and composited.
sampled wet or dry. Samples are collected and homogenised prior to splitting to ensure sample
representivity. ~1.5kg composite samples are processed.
Where drillhole lengths are composited into longer samples for processing, an
equivalent mass is taken from each primary sample to make up the composite.
The primary composite sample is considered representative for this style of
mineralisation and is consistent with industry standard practice.
For all sample types, the nature, quality and appropriateness of the sample Techniques for sample preparation are detailed on SOP documents verified by
preparation technique. Placer and MSA Resource Geologists.
Sample preparation is recorded on a standard flow sheet and detailed QA/QC is
undertaken on all samples. Sample preparation techniques and QA/QC protocols
are appropriate for mineral determination and support the resource
classifications as stated.
Quality control procedures adopted for all sub-sampling stages to maximise The sampling equipment is cleaned after each sub-sample is taken. Field
representivity of samples. duplicate, laboratory replicate and standard sample statistical analysis is
employed to manage sample precision and analysis accuracy.
Measures taken to ensure that the sampling is representative of the in situ Sample size analysis is completed to verify sampling accuracy. Field
material collected, including for instance results for field duplicates are collected for precision analysis of riffle splitting. SOPs
duplicate/second-half sampling. consider sample representivity. Results indicate a sufficient level of
precision for mineral resource classification.
Whether sample sizes are appropriate to the grain size of the material being The sample size is considered appropriate for the material sampled.
sampled.
Quality of assay data and laboratory tests The nature, quality and appropriateness of the assaying and laboratory Rutile
procedures used and whether the technique is considered partial or total.
All sample preparation is completed at Sovereign Metals Malawi onsite
laboratory (SSL) located in Lilongwe. The sample preparation methods are
considered quantitative to the point where a non-magnetic (NMag) concentrate
is generated.. Since June 2023 SSL has included the magnetic separation
process to create the NMag concentrate, which is then sent to an external
laboratory for TiO(2) analysis. Prior to 2023 the Heavy Mineral Concentrate
(HMC) was sent to AML Laboratory in Perth for separation.
Final results generated are for recovered rutile i.e, the % mass of the sample
that is rutile that can be recovered to the non-magnetic component of a HMC.
The current SSL Laboratory workflow is:
· Dry sample in oven for 1 hour at 105℃
· Soak in water with 1% Tetrasodium pyrophosphate (TSPP) for 12 hours
and lightly agitate
· Wet screen at 5mm, 600µm and 45µm to remove oversize and slimes
material, since October 2025 a 2mm to 5mm size fraction has also been screened
to represent the +2mm portion produced from the planned processing plant.
· Dry +45µm -600mm (sand fraction) in oven for 1 hour at 105℃
· Pass +45µm -600mm (sand fraction) across wet table to generate a
HMC.
· Dry HMC in oven for 30 minutes at 105℃
· Magnetic separation of the HMC by Carpco magnet @ 16,800G (2.9Amps)
into a magnetic (Mag) and non-magnetic (NMag) fraction
· Send NM to external laboratory for TiO2% (and other elements) XRF
analysis
Various workflows were use to produce HMC, Magnetic separation and external
laboratory TiO2% plus other XRF analysis prior to June 2023
Work flow codes and number of samples impacted are presented below:
WORKFLOW Num Sample Metres
DIA-AML-IT 190 635.0
DIA-AML-ALS 877 2,860.2
LLW-AML-IT 408 1,465.5
LLW-AML-ALS 3,321 8,745.8
LLW-LLW-ALS 5,272 9,279.3
LLW-LLW-SS 7,768 12,959.2
Total 17,836 35,944.9
DIA-AML-IT and DIA-AML-ALS
· The Sand fractions are sent to Diamantina Laboratories, Perth.
Split ~150g of sand fraction for HLS using Tetrabromoethane (TBE, SG 2.96g/cc)
as the liquid heavy media to generate HMC.
(Heavy liquid separation (HLS) of the HM is no longer required and a HM result
is not reported in the updated MRE. The HMC prepared via wet-table, gravity
separation at the Lilongwe Laboratory provides an ideal sample for subsequent
magnetic separation and XRF.)
· Bag the HMC fraction and send to AML Perth for quantitative
separation.
· The resulting NM fractions are sent to either ALS Metallurgy Perth
or Intertek Perth for quantitative XRF analysis.
LLW-AML-IT and LLW-AML-ALS
· Bag HMC fraction and send to Perth, Australia for quantitative
separation at AML
· The resulting NM fractions are sent to either ALS Metallurgy Perth
or Intertek Perth for quantitative XRF analysis.
LLW-LLW-ALS
· The NM fractions are sent to ALS Metallurgy Perth for quantitative
XRF analysis. Samples receive XRF_MS and are analysed for: TiO2, Al2O3, CaO,
Cr2O3, Fe2O3, K2O, MgO, MnO, SiO2, V2O5, ZrO2, HfO2.
LLW-LLW-SS
· The NM fractions are sent to Scientific Servies South Africa for
quantitative XRF analysis. Samples are analysed for: TiO2, Nd2O3, CeO2, La2O3,
BaO, HfO2, Nb2O5, ZrO2, Y2O3, Fe2O3, MnO, Cr2O3, V2O5, CaO, K2O, P2O5, SiO2,
Al2O3, MgO, NaO2
The number of Rutile samples used in the MRE by hole type are:
HTYPE_4 Num Sample Metres
AC 6,511 11,382.6
HA 6,608 17,919.4
PTDD 3,359 5,190.2
SA 1,358 1,452.7
Total 18,994 35,944.9
Graphite
All graphite samples were processed at Intertek-Genalysis Johannesburg and
Perth via method C72/CSA.
750g of each 1.5kg graphite sample is pulverised to -75um with a 150g
sub-sample dissolved in dilute hydrochloric acid to liberate carbonate carbon.
The solution is filtered using a filter paper and the collected residue is the
dried to 425°C in a muffle oven to drive off organic carbon. The 150g dried
sample is then combusted using an Eltra CS-800 induction furnace infra-red
Carbon / Sulphur analyser er to yield total graphitic or TGC as a percentage
of the total rock.
The number of samples analysed for TGC and used in the MRE by hole type are:
HTYPE_4 Num Sample Metres
AC 6,349 11,110.0
HA 5,999 16,563.4
PTDD 3,084 4,971.6
SA 1,257 1,293.7
Total 16,689 33,938.7
In some holes (especially near the surface) no graphite float was detected,
these samples were not sent for analysis and were set to waste TGC grades:
HTYPE_4 Num Sample Metres
AC 87 146.0
HA 751 1,545.2
PTDD 225 204.3
Total 1,063 1,895.5
For geophysical tools, spectrometers, Acceptable levels of accuracy and precision have been established. No pXRF
methods are used for quantitative determination.
handheld XRF instruments, etc., the parameters used in determining the
analysis including instrument make and model, reading times, calibrations
factors applied and their derivation, etc.
Nature of quality control procedures Sovereign uses internal and externally sourced wet screening reference
material inserted into samples batches at a rate of 1 in 20. The externally
adopted (e.g. standards, blanks, duplicate, external laboratory checks) and sourced, certified standard reference material for HM and Slimes assessment is
whether acceptable levels of accuracy (i.e. lack of bias) and precision have provided by Placer Consulting.
been established.
Accuracy monitoring of the analytical work is achieved through submission of
certified reference materials (CRM's). ALS, Scientific Services and Intertek
all use internal CRMs and duplicates on XRF analyses. Sovereign also inserts
CRMs into the sample batches at a rate of 1 in 20.
Three Rutile CRMs are used by Sovereign and range from 35% - 95% TiO2.
Three Graphite CRMs are used by Sovereign and range from 3% - 25% TGC.
Analysis of sample duplicates is undertaken by standard statistical
methodologies (Scatter, Pair Difference and QQ Plots) to test for bias and to
ensure that sample splitting is representative. Standards determine assay
accuracy performance, monitored on control charts, where failure (beyond 3SD
from the mean) may trigger re-assay of the affected batch.
Examination of the QA/QC sample data indicates satisfactory performance of
field sampling protocols and assay laboratories providing acceptable levels of
precision and accuracy.
Acceptable levels of accuracy and precision are displayed in statistical
analyses to support the resource classifications as applied to the estimate.
Verification of sampling & assaying The verification of significant intersections by either independent or Results are reviewed in cross-section using Datamine Studio RM and either
alternative company personnel. Micromine or LeapFrog software and any spurious results are investigated.
Extreme high grades are not encountered for either rutile or graphite.
The use of twinned holes. Twinned holes are drilled across a geographically dispersed area to determine
short-range geological and assay field variability for the resource
estimation. Twins were primarily: HA and AC; PTDD and AC and more recently SA
and AC. A total of 389 twin holes have been drilled of which 135 are twins of
the same drilling type, the remainder being comparisons between different
drilling methods. All twins are within 5m of each other.
The October/November AC 115mm drilling program included SA 300mm twins to the
base of the FERP layer, a total of 55 twin holes. The comparison showed a 2.5%
lower Rut95 grade in the AC, with the difference primarily in the higher grade
near surface material. This difference was not unexpected due to difference in
sample diameter. The results demonstrate the improved quality of AC recovery
using the 115mm drill bit.
Comparison between the drilling methods shows some bias in the sizing
distributions particularly in the volume of +45 um recovered due to behaviour
of coarse size fractions at the drill face. Key parameters are: sample
diameter; downhole air pressure; cyclone efficiency; moisture content; and
drill bit configuration. The variances observed fall within the grades
tolerances expected for this type of deposit and have been taken into account
in the MRE classification.
Documentation of primary data, data entry procedures, data verification, data All data is collected electronically using coded templates and logging
storage (physical and electronic) protocols. software. This data is then imported to a SQL Database and validated both
automatically (on upload) and manually (by viewing sections).
Discuss any adjustment to assay data. Assay data adjustments are made to convert laboratory collected weights to
assay field percentages and to account for moisture.
QEMSCAN of the NMag fraction shows dominantly clean and liberated rutile
grains and confirms rutile is the only titanium species in the NMag fraction.
Recovered rutile is defined and reported here as: TiO2 recovered in the +45 to
-600um range to the NMag concentrate fraction as a % of the total primary,
dry, raw sample mass divided by 95% (to represent an approximation of final
product specifications). i.e., recoverable rutile within the whole sample.
Graphite grade (TGC%) is not adjusted. In some holes where panning of the
sample encountered no graphite flakes, a waste grade of 0.01% TGC was applied.
Location of data points Accuracy and quality of surveys used to locate drill holes (collar and A Trimble R2 Differential GPS is used to pick up the drill hole collars. Daily
down-hole surveys), trenches, mine workings and other locations used in capture at a registered reference marker ensures equipment remains in
Mineral Resource estimation. calibration.
No downhole surveying of any holes is completed. Given the horizontal nature
of geology and mineralisation and shallow depths of the holes, any drill hole
deviation will have very limited impact on the estimation of block grades.
Specification of the grid system used. WGS84 UTM Zone 36 South.
Quality and adequacy of topographic The digital terrane model (DTM) was generated by wireframing a 20m-by-
control. 20m lidar drone survey point array, commissioned by SVM in March 2022.
Non-topographic features were removed from the survey points file prior to
generating the topographical wireframe for resource model construction. The
high resolution 3D drone aerial survey was executed utilising a RTK GPS
equipped Zenith aircraft with accuracy of <10cm ground sampling distance
(GSD). Post-processing includes the removal of features that do not include
the undisturbed ground surface (cemeteries, pits, mounds, etc.)
Topography for North - South extensions to the mineralisation outside the
limits of the lidar DTM was created using the publicly available satellite
topography. This was adjusted using DGPS drill hole collars to improve local
accuracy.
The DTM is suitable for the classification of the MRE
Data spacing & distribution Data spacing for reporting of Exploration Results. Preliminary regional exploration is completed on a nominal 800m grid. The
infill HA drilling is spaced nominally 400m along the 400m spaced drill-
lines. Further infill is completed with PT and AC holes similarly spaced at an
offset grid. In some areas recent PT, AC and SA drilling has been completed on
a 200m offset grid. The resultant infill 141m and 283m equilateral spacing is
deemed to adequately define the mineralisation in the MRE.
The PT, AC and SA holes are selectively placed throughout the deposit to
ensure a broad geographical and lithological spread for the analysis.
Whether the data spacing and distribution is sufficient to establish the The drill spacing and distribution is considered to be sufficient to establish
degree of geological and grade continuity appropriate for the Mineral Resource a degree of geological and grade continuity appropriate for the Mineral
and Ore Reserve estimation procedure(s) and classifications applied. Resource estimation.
Variogram analysis completed using Supervisor software informs the optimal
drill and sample spacing for the MRE. Based on these results and the
experience of the Competent Person, the data spacing and distribution is
considered adequate for the definition of mineralisation and adequate for
Mineral Resource Estimation.
Whether sample compositing has been applied. All samples were assigned a Weathering domain code based on the geology
logging and 3D weathering profile interpretation. Separate grade domains for
both rutile and graphite were interpreted based on nominal mineralisation
cut-offs.
Compositing to create a single composite representing the unique weathering
and mineralisation domain down each hole was completed.
Orientation of data in relation to geological structure Whether the orientation of sampling achieves unbiased sampling of possible Sample orientation is vertical and approximately perpendicular to the
structures and the extent to which this is known considering the deposit type orientation of the mineralisation, which results in true thickness estimates,
limited by the sampling interval as applied. Drilling and sampling are carried
out on a regular grid.
If the relationship between the drilling orientation and the orientation of There is no apparent bias arising from the orientation of the drill holes with
key mineralised structures is considered to have introduced a sampling bias, respect to the orientation of the deposit.
this should be assessed and reported if material.
Sample security The measures taken to ensure sample security Samples are stored in secure storage from the time of drilling, through
gathering, compositing and analysis. The samples are sealed as soon as site
preparation is complete.
A reputable international transport company with shipment tracking enables a
chain of custody to be maintained while the samples move from Malawi to South
Africa and Australia. Samples are again securely stored once they arrive and
are processed at respective laboratories.
At each point of the sample workflow the samples are inspected by a company
representative to monitor sample condition. Each laboratory confirms the
integrity of the samples upon receipt.
Audits or reviews The results of any audits or reviews of sampling techniques and data The CP Jeremy Witley has reviewed and advised on all stages of data
collection, sample processing, QA protocol and Mineral Resource Estimation.
Field and in-country lab visits have been completed by Mr Witley. A high
standard of operation, procedure and personnel was observed and reported.
DIA-AML-IT and DIA-AML-ALS
· The Sand fractions are sent to Diamantina Laboratories, Perth.
Split ~150g of sand fraction for HLS using Tetrabromoethane (TBE, SG 2.96g/cc)
as the liquid heavy media to generate HMC.
(Heavy liquid separation (HLS) of the HM is no longer required and a HM result
is not reported in the updated MRE. The HMC prepared via wet-table, gravity
separation at the Lilongwe Laboratory provides an ideal sample for subsequent
magnetic separation and XRF.)
· Bag the HMC fraction and send to AML Perth for quantitative
separation.
· The resulting NM fractions are sent to either ALS Metallurgy Perth
or Intertek Perth for quantitative XRF analysis.
LLW-AML-IT and LLW-AML-ALS
· Bag HMC fraction and send to Perth, Australia for quantitative
separation at AML
· The resulting NM fractions are sent to either ALS Metallurgy Perth
or Intertek Perth for quantitative XRF analysis.
LLW-LLW-ALS
· The NM fractions are sent to ALS Metallurgy Perth for quantitative
XRF analysis. Samples receive XRF_MS and are analysed for: TiO2, Al2O3, CaO,
Cr2O3, Fe2O3, K2O, MgO, MnO, SiO2, V2O5, ZrO2, HfO2.
LLW-LLW-SS
· The NM fractions are sent to Scientific Servies South Africa for
quantitative XRF analysis. Samples are analysed for: TiO2, Nd2O3, CeO2, La2O3,
BaO, HfO2, Nb2O5, ZrO2, Y2O3, Fe2O3, MnO, Cr2O3, V2O5, CaO, K2O, P2O5, SiO2,
Al2O3, MgO, NaO2
The number of Rutile samples used in the MRE by hole type are:
HTYPE_4 Num Sample Metres
AC 6,511 11,382.6
HA 6,608 17,919.4
PTDD 3,359 5,190.2
SA 1,358 1,452.7
Total 18,994 35,944.9
Graphite
All graphite samples were processed at Intertek-Genalysis Johannesburg and
Perth via method C72/CSA.
750g of each 1.5kg graphite sample is pulverised to -75um with a 150g
sub-sample dissolved in dilute hydrochloric acid to liberate carbonate carbon.
The solution is filtered using a filter paper and the collected residue is the
dried to 425°C in a muffle oven to drive off organic carbon. The 150g dried
sample is then combusted using an Eltra CS-800 induction furnace infra-red
Carbon / Sulphur analyser er to yield total graphitic or TGC as a percentage
of the total rock.
The number of samples analysed for TGC and used in the MRE by hole type are:
HTYPE_4 Num Sample Metres
AC 6,349 11,110.0
HA 5,999 16,563.4
PTDD 3,084 4,971.6
SA 1,257 1,293.7
Total 16,689 33,938.7
In some holes (especially near the surface) no graphite float was detected,
these samples were not sent for analysis and were set to waste TGC grades:
HTYPE_4 Num Sample Metres
AC 87 146.0
HA 751 1,545.2
PTDD 225 204.3
Total 1,063 1,895.5
For geophysical tools, spectrometers,
handheld XRF instruments, etc., the parameters used in determining the
analysis including instrument make and model, reading times, calibrations
factors applied and their derivation, etc.
Acceptable levels of accuracy and precision have been established. No pXRF
methods are used for quantitative determination.
Nature of quality control procedures
adopted (e.g. standards, blanks, duplicate, external laboratory checks) and
whether acceptable levels of accuracy (i.e. lack of bias) and precision have
been established.
Sovereign uses internal and externally sourced wet screening reference
material inserted into samples batches at a rate of 1 in 20. The externally
sourced, certified standard reference material for HM and Slimes assessment is
provided by Placer Consulting.
Accuracy monitoring of the analytical work is achieved through submission of
certified reference materials (CRM's). ALS, Scientific Services and Intertek
all use internal CRMs and duplicates on XRF analyses. Sovereign also inserts
CRMs into the sample batches at a rate of 1 in 20.
Three Rutile CRMs are used by Sovereign and range from 35% - 95% TiO2.
Three Graphite CRMs are used by Sovereign and range from 3% - 25% TGC.
Analysis of sample duplicates is undertaken by standard statistical
methodologies (Scatter, Pair Difference and QQ Plots) to test for bias and to
ensure that sample splitting is representative. Standards determine assay
accuracy performance, monitored on control charts, where failure (beyond 3SD
from the mean) may trigger re-assay of the affected batch.
Examination of the QA/QC sample data indicates satisfactory performance of
field sampling protocols and assay laboratories providing acceptable levels of
precision and accuracy.
Acceptable levels of accuracy and precision are displayed in statistical
analyses to support the resource classifications as applied to the estimate.
Verification of sampling & assaying
The verification of significant intersections by either independent or
alternative company personnel.
Results are reviewed in cross-section using Datamine Studio RM and either
Micromine or LeapFrog software and any spurious results are investigated.
Extreme high grades are not encountered for either rutile or graphite.
The use of twinned holes.
Twinned holes are drilled across a geographically dispersed area to determine
short-range geological and assay field variability for the resource
estimation. Twins were primarily: HA and AC; PTDD and AC and more recently SA
and AC. A total of 389 twin holes have been drilled of which 135 are twins of
the same drilling type, the remainder being comparisons between different
drilling methods. All twins are within 5m of each other.
The October/November AC 115mm drilling program included SA 300mm twins to the
base of the FERP layer, a total of 55 twin holes. The comparison showed a 2.5%
lower Rut95 grade in the AC, with the difference primarily in the higher grade
near surface material. This difference was not unexpected due to difference in
sample diameter. The results demonstrate the improved quality of AC recovery
using the 115mm drill bit.
Comparison between the drilling methods shows some bias in the sizing
distributions particularly in the volume of +45 um recovered due to behaviour
of coarse size fractions at the drill face. Key parameters are: sample
diameter; downhole air pressure; cyclone efficiency; moisture content; and
drill bit configuration. The variances observed fall within the grades
tolerances expected for this type of deposit and have been taken into account
in the MRE classification.
Documentation of primary data, data entry procedures, data verification, data
storage (physical and electronic) protocols.
All data is collected electronically using coded templates and logging
software. This data is then imported to a SQL Database and validated both
automatically (on upload) and manually (by viewing sections).
Discuss any adjustment to assay data.
Assay data adjustments are made to convert laboratory collected weights to
assay field percentages and to account for moisture.
QEMSCAN of the NMag fraction shows dominantly clean and liberated rutile
grains and confirms rutile is the only titanium species in the NMag fraction.
Recovered rutile is defined and reported here as: TiO2 recovered in the +45 to
-600um range to the NMag concentrate fraction as a % of the total primary,
dry, raw sample mass divided by 95% (to represent an approximation of final
product specifications). i.e., recoverable rutile within the whole sample.
Graphite grade (TGC%) is not adjusted. In some holes where panning of the
sample encountered no graphite flakes, a waste grade of 0.01% TGC was applied.
Location of data points
Accuracy and quality of surveys used to locate drill holes (collar and
down-hole surveys), trenches, mine workings and other locations used in
Mineral Resource estimation.
A Trimble R2 Differential GPS is used to pick up the drill hole collars. Daily
capture at a registered reference marker ensures equipment remains in
calibration.
No downhole surveying of any holes is completed. Given the horizontal nature
of geology and mineralisation and shallow depths of the holes, any drill hole
deviation will have very limited impact on the estimation of block grades.
Specification of the grid system used.
WGS84 UTM Zone 36 South.
Quality and adequacy of topographic
control.
The digital terrane model (DTM) was generated by wireframing a 20m-by-
20m lidar drone survey point array, commissioned by SVM in March 2022.
Non-topographic features were removed from the survey points file prior to
generating the topographical wireframe for resource model construction. The
high resolution 3D drone aerial survey was executed utilising a RTK GPS
equipped Zenith aircraft with accuracy of <10cm ground sampling distance
(GSD). Post-processing includes the removal of features that do not include
the undisturbed ground surface (cemeteries, pits, mounds, etc.)
Topography for North - South extensions to the mineralisation outside the
limits of the lidar DTM was created using the publicly available satellite
topography. This was adjusted using DGPS drill hole collars to improve local
accuracy.
The DTM is suitable for the classification of the MRE
Data spacing & distribution
Data spacing for reporting of Exploration Results.
Preliminary regional exploration is completed on a nominal 800m grid. The
infill HA drilling is spaced nominally 400m along the 400m spaced drill-
lines. Further infill is completed with PT and AC holes similarly spaced at an
offset grid. In some areas recent PT, AC and SA drilling has been completed on
a 200m offset grid. The resultant infill 141m and 283m equilateral spacing is
deemed to adequately define the mineralisation in the MRE.
The PT, AC and SA holes are selectively placed throughout the deposit to
ensure a broad geographical and lithological spread for the analysis.
Whether the data spacing and distribution is sufficient to establish the
degree of geological and grade continuity appropriate for the Mineral Resource
and Ore Reserve estimation procedure(s) and classifications applied.
The drill spacing and distribution is considered to be sufficient to establish
a degree of geological and grade continuity appropriate for the Mineral
Resource estimation.
Variogram analysis completed using Supervisor software informs the optimal
drill and sample spacing for the MRE. Based on these results and the
experience of the Competent Person, the data spacing and distribution is
considered adequate for the definition of mineralisation and adequate for
Mineral Resource Estimation.
Whether sample compositing has been applied.
All samples were assigned a Weathering domain code based on the geology
logging and 3D weathering profile interpretation. Separate grade domains for
both rutile and graphite were interpreted based on nominal mineralisation
cut-offs.
Compositing to create a single composite representing the unique weathering
and mineralisation domain down each hole was completed.
Orientation of data in relation to geological structure
Whether the orientation of sampling achieves unbiased sampling of possible
structures and the extent to which this is known considering the deposit type
Sample orientation is vertical and approximately perpendicular to the
orientation of the mineralisation, which results in true thickness estimates,
limited by the sampling interval as applied. Drilling and sampling are carried
out on a regular grid.
If the relationship between the drilling orientation and the orientation of
key mineralised structures is considered to have introduced a sampling bias,
this should be assessed and reported if material.
There is no apparent bias arising from the orientation of the drill holes with
respect to the orientation of the deposit.
Sample security
The measures taken to ensure sample security
Samples are stored in secure storage from the time of drilling, through
gathering, compositing and analysis. The samples are sealed as soon as site
preparation is complete.
A reputable international transport company with shipment tracking enables a
chain of custody to be maintained while the samples move from Malawi to South
Africa and Australia. Samples are again securely stored once they arrive and
are processed at respective laboratories.
At each point of the sample workflow the samples are inspected by a company
representative to monitor sample condition. Each laboratory confirms the
integrity of the samples upon receipt.
Audits or reviews
The results of any audits or reviews of sampling techniques and data
The CP Jeremy Witley has reviewed and advised on all stages of data
collection, sample processing, QA protocol and Mineral Resource Estimation.
Field and in-country lab visits have been completed by Mr Witley. A high
standard of operation, procedure and personnel was observed and reported.
Section 2 - Reporting of Exploration Results
Criteria Explanation Commentary
Mineral tenement & land tenure status Type, reference name/number, location and ownership including agreements or The Company owns 100% of the following Exploration Licences (ELs) EL0609,
material issues with third parties such as joint ventures, partnerships, EL0582 and EL0710 and Retention Licences RTL0035/25 to RTL0046/25 (previously
overriding royalties, native title interests, historical sites, wilderness or EL0492) relevant to this MRE update. The EL's were issued in accordance with
national park and environment settings. Mines and Minerals Act (2023) and are held in the Company's wholly-owned
Malawi- registered subsidiaries.
A 5% royalty is payable to the government upon mining and a 2% of net profit
royalty is payable to the original project vendor.
No significant native vegetation or reserves exist in the area. The region is
intensively cultivated for agricultural crops.
The security of the tenure held at the time of reporting along with any known The tenements are in good standing and no known impediments to exploration or
impediments to obtaining a licence to mining exist.
operate in the area.
Exploration done by other parties Acknowledgement and appraisal of exploration by other parties. Sovereign is a first-mover in the discovery and definition of residual rutile
and graphite resources in Malawi. No other parties are, or have been, involved
in exploration.
Geology Deposit type, geological setting and style of mineralisation The rutile deposit type is considered a residual placer formed by the intense
weathering of rutile-rich basement paragneisses and variable enrichment by
elluvial processes.
Rutile occurs in a mostly topographically flat area west of Malawi's capital,
known as the Lilongwe Plain, where a deep tropical weathering profile is
preserved. A typical profile from top to base is generally soil ("SOIL" 0-1m)
ferruginous pedolith ("FERP", 1-4m), mottled zone ("MOTT", 4-7m), pallid
saprolite ("PSAP", 7-9m), saprolite ("SAPL", 9-25m), saprock ("SAPR", 25-35m)
and fresh rock ("FRESH" >35m). Any rutile located in SAPR and FRESH is not
considered in this Mineral Resource Estimate
The graphite mineralisation occurs as multiple bands of graphite gneisses,
hosted within a broader Proterozoic paragneiss package. In the Kasiya areas
specifically, the preserved weathering profile hosts significant vertical
thicknesses, from near surface, of graphite mineralisation.
Drill hole information A summary of all information material to the understanding of the exploration All intercepts relating to the Kasiya Deposit have been included in public
results including a tabulation of the following information for all Material releases during each phase of exploration and in this report. Releases
drill holes: easting and northings of the drill hole collar; elevation or RL included all collar and composite data and these can be viewed on the Company
(Reduced Level-elevation above sea level in metres of the drill hole collar); website.
dip and azimuth of the hole; down hole length and interception depth; and hole
length There are no further drill hole results that are considered material to the
understanding of the exploration results. Identification of the broad zone of
mineralisation is made via multiple intersections of drill holes and to list
them all would not give the reader any further clarification of the
distribution of mineralisation throughout the deposit.
If the exclusion of this information is justified on the basis that the Rutile grades from the 2024 AC drill program have been excluded from this MRE
information is not Material and this exclusion does not detract from the update as there was an unexpected issue with cyclone hangup which where
understanding of the report, the Competent Person should clearly explain why occurred introduced a material sizing bias which affects the reliability of
this is the case the rutile grade estimate.
Geology logging and the mineralisation domains defined from the 2024 AC
drilling have been incorporated to enhance confidence in the geological model.
Data aggregation methods In reporting Exploration Results, weighting averaging techniques, maximum All results reported are of a length-weighted average of in-situ grades.
and/or minimum grade truncations (e.g. cutting of high-grades) and cut-off
grades are usually Material and should be stated. A nominal bottom cut of 0.7% rutile is used, based on preliminary assessment
of resource product value and anticipated cost of operations.
Where aggregate intercepts incorporate short lengths of high-grade results and No data aggregation was required.
longer lengths of low-grade results, the procedure used for such aggregation
should be stated and some typical examples of such aggregations should be
shown in detail.
The assumptions used for any reporting of metal equivalent values should be Rutile Equivalent (Rut_Eq = Rutile+(TGC*0.5735) - where applicable
clearly stated.
Formula: (Rutile Grade x Recovery x Rutile Price) + (Graphite Grade x Recovery
x Graphite Price) / Rutile Price.
Commodity Prices:
· Rutile price: US$1,294/t
· Graphite price: US$1,099/t
Metallurgical Recovery to Product:
· Rutile Recovery: 97.6%
· Graphite Recovery: 70.4%
Relationship between mineralisation widths & intercept lengths These relationships are particularly important in the reporting of Exploration The mineralisation has been released by weathering of the underlying, layered
Results. gneissic bedrock that broadly trends NE-SW at Kasiya North and N-S at Kasiya
South and far North. It lies in a laterally extensive superficial blanket with
high- grade zones reflecting the broad bedrock strike orientation of ~045° in
the North of Kasiya and 360° in the South and far North of Kasiya.
If the geometry of the mineralisation with respect to the drill hole angle is The mineralisation is laterally extensive where the entire weathering profile
known, its nature should be reported. is preserved and not significantly eroded. Minor removal of the mineralised
profile has occurred in alluvial channels. These areas are adequately defined
by the drilling pattern and topographical control for the resource estimate.
If it is not known and only the down hole lengths are reported, there should Downhole widths approximate true widths limited to the sample intervals
be a clear statement to this effect (e.g. 'down hole length, true width not applied. Mineralisation remains open at depth and in areas coincident with
known'. high-rutile grade lithologies in basement rocks.
Graphite results are approximate true width as defined by the sample interval
and are typically higher in the deeper portions of the weathering profile.
Diagrams Appropriate maps and sections (with scales) and tabulations of intercepts Refer to figures and diagrams provided in this report.
should be included for any significant discovery being reported. These should
include, but not be limited to a plan view of the drill collar locations and
appropriate sectional views.
Balanced Where comprehensive reporting of all Exploration Results is not practicable, All results are included in this report and in previous releases. These are
representative reporting of both low and high-grades and/or widths should be accessible on the Company's webpage.
reporting practiced to avoid misleading reporting of exploration results.
Other substantive exploration data Other exploration data, if meaningful and material, should be reported Limited lateritic duricrust has been variably developed at Kasiya, as is
including (but not limited to: geological observations; geophysical survey typical in tropical highland areas subjected to seasonal wet/dry cycles.
results; geochemical survey results; bulk samples - size and method of Lithological logs record drilling refusal in just under 2% of the HA/PT drill
treatment; metallurgical test results; bulk density, groundwater, geotechnical database. No drilling refusal was recorded above the saprock interface by AC
and rock characteristics; potential deleterious or contaminating substances. drilling.
Slimes (-45 µm) averages 46wt% in the primary rutile mineralisation zone.
Separation test work conducted at AML demonstrates the success in applying a
contemporary mineral sands flowsheet in treating this material and achieving
excellent rutile recovery.
Sample quality (representivity) is established by statistical analysis of
comparable sample intervals.
Several generations of QEMSCAN analysis of the NMag performed at ALS
Metallurgy, shows dominantly clean and liberated rutile grains and confirms
rutile is the only titanium species in the NMag fraction.
Further work The nature and scale of planned further work (e.g. test for lateral extensions Additional waste rock characterisation work relevant to mining scale, related
or depth extensions or large-scale step-out drilling). to barren clay horizons related to recent alluvial weathering (dambos),
amphibolite and pegmatitic zones.
A greater understanding of the lithological character and extent of those
basement units, where high-grade (>1%) rutile persists at the saprock
interface, may assist in focusing further resource definition and exploration
targeting.
Further metallurgical assessment is suggested to characterise rutile quality
and establish whether any chemical variability is inherent across the deposit.
Further laboratory and metallurgical analysis of the Mag fraction to improve
the definition of the Rare Earth Elements (REE) associated with the presence
of Monazite in the Mag fraction.
Further analysis of other potential HM associated with the byproducts of
rutile production.
Diagrams clearly highlighting the areas of possible extensions, including the Refer to diagrams in the body of this report and in previous releases. These
main geological interpretations and future drilling areas, provided this are accessible on the Company's website.
information is not commercially sensitive.
Section 3 - Estimation and Reporting of Mineral Resources
Criteria JORC Code explanation Commentary
Database integrity Measures taken to ensure that data has not been corrupted by, for example, Data are manually entered into database tables according to SOPs and
transcription or keying errors, between its initial collection and its use for conforming to company field names and classifications. These are migrated to
Mineral Resource estimation purposes. Datashed5 (prior to June 2024) and now MX Deposit database managed internally
by the Company (with external support from Cape Town based exploration company
RES) with validation and quarantine capability. Relevant tables from the
database are exported to csv format and forwarded to MSA for independent
review.
Data validation procedures used. Validation of the primary data include checks for duplicate or overlapping
intervals, missing survey data, missing assay data or missing lithological
data.
Statistical, out-of-range, distribution, error and missing data validation is
completed by MSA on data sets before being compiled into a de-surveyed drill
hole file and interrogated in 3D using Datamine Studio RM software.
All questions relating to the input data are forwarded to the client for
review and resolution prior to resource estimation.
The type and number of holes used in the MRE are:
HTYPE_4 Num Holes Metres Drilled
AC 538 11,636.7
HA 1,938 18,066.0
PTDD 533 5,650.7
SA 178 1,725.9
Total 3,187 37,079.3
Additional sampling included open pits, channel sampling of the trial mining
area which were used for checking and validation of the various drilling
methods:
HTYPE_4 Num Holes Metres Drilled
CH 54 315.0
CL 10 40.0
HACL 279 829.6
PIT 87 400.3
RC 9 279.0
PC 17 91.4
Total 456 1,955.3
Site visits Comment on any site visits undertaken by the Competent Person and the outcome Field and SSL laboratory visits were completed over a 1-week period in
of those visits. November 2024 and June 2025. A high standard of operation, procedure and
personnel was observed and reported.
If no site visits have been undertaken indicate why this is the case. Not applicable
Geological interpretation Confidence in (or conversely, the uncertainty of) the geological There is a high degree of repeatability and uniformity in the geological
interpretation of the mineral deposit. character of the Kasiya Deposit demonstrated by lithological logging of AC, PT
core and HA samples. Satellite imagery and airborne geophysical data provided
guidance for interpreting the strike continuity of the deposit.
Drill hole intercept logging and assay results (AC, PT, SA and HA),
stratigraphic interpretations from drill core and geological logs of drill
data have formed the basis for the geological interpretation. The drilling
exclusively targeted the SOIL, FERP, MOTT and SAPL weathering horizons, with
no sampling of the SAPR and below the upper level of the fresh rock (FRESH)
domain.
Nature of the data used and of any assumptions made. No assumptions were made.
The effect, if any, of alternative interpretations on Mineral Resource No alternative interpretations on Mineral Resource Estimation are offered.
estimation.
The use of geology in guiding and controlling Mineral Resource estimation. The mineral resource is constrained by the drill array plus up to 400m area of
influence from nearest drilling.
The topographical DTM constrains the vertical extent of the resource.
The primary domain control is weathering type - SOIL+FERP, MOTT, PSAP and
SAPL. This is further sub-divided into rutile mineralisation (nominally
>=0.5% Rutile) and graphite mineralisation (nominally >=0.6% TGC). The
mineralisation domains are treated independently of each other.
The base to mineralisation is constrained by a DTM representing the bottom of
drilling.
AC drilling has accurately defined depth to basement at the saprock interface,
which has been modelled in the MRE where intersected.
The factors affecting continuity both of grade and geology. Rutile grade is generally concentrated in surface regolith horizons. Deposit
stratigraphy and weathering is consistent along and across strike. Rutile
grade trend is oriented at 45 degrees at Kasiya North and 360 degrees at
Kasiya South and far North, which mimics the underlying basement source rocks
and residual topography. Rutile varies across strike as a result of the
layering of mineralised and non-mineralised basement rocks.
Areas containing near surface clay lenses, amphibolite and narrow cross
striking pegmatitic rocks are barren of rutile and graphite. These zones have
been modelled and excluded from the mineralisation domains.
Dimensions The extent and variability of the Mineral Resource expressed as length (along The Kasiya mineralised footprint strikes N - S & NE - SW, is 72km long and
strike or otherwise), plan width, and depth below surface to the upper and approximately 20km at its widest section. The currently defined surface extent
lower limits of the Mineral Resource. of >=0.7% rutile is about 268.6km2.
The mineral resource occurs from surface to the saprolite-saprock interface,
which is typically in the order of 15m, although can attain localised
thicknesses in excess of 25m. The deposit thins towards the edges to
approximately 5m and pinches out in the drainage channels.
Estimation and modelling techniques The nature and appropriateness of the estimation technique(s) applied and key Datamine Studio RM, LeapFrog and Supervisor software are used for the data
assumptions, including treatment of extreme grade values, domaining, analysis, variography, geological interpretation and resource estimation.
interpolation parameters and maximum distance of extrapolation from data
points. If a computer assisted estimation method was chosen include a A 3D block model honouring the geology boundaries which included weathering
description of computer software and parameters used. horizons; barren mafic intrusives; surface clay horizons, cross striking
pegmatitic zones and presence of barren or low grade amphibolite was created.
The model was also coded with the tenement EL codes, rock in-situ dry bulk
density and moisture content.
Rutile mineralisation was defined as the last intercept >=2m down hole
exceeding 0.5% Rutile. As a general rule, rutile grade is highest at the
surface gradually reducing in grade with depth. Using this guideline very
little internal low grade/waste is introduced. The resulting sample point data
was used to create the bounding lower surface for a rutile mineralisation DTM.
Additional manual points were interpreted in section by section to ensure
consistency, especially in areas with wider spaced drilling.
Graphite mineralisation was defined as the highest up hole intercept >-2m
exceeding 0.6% TGC. As a general rule TGC grade is highest at depth gradually
reducing in grade closer to the surface. Using this guideline very little
internal low grade/waste is introduced. Similarly to rutile, a graphite
mineralisation upper limit DTM was constructed. The lower limit of graphite
mineralisation was either the base of drilling or the top of SAPR if drilling
intersected SAPR.
Eight grade domains were created, 4 mineralised and 4 low grade / waste for
both rutile and graphite, based on the combination of weathering type inside
or outside the mineralisation DTM's. Samples were composited to 1 sample per
drillhole per domain. Rutile and TGC samples were treated independently as
there is no correlation between rutile and TGC grades.
The composite populations generally approximated normal distributions with
some -ve and/or +ve skewness relating to the imposed mineralisation boundary.
Ordinary Kriging (OK) was considered the best grade estimator for both rutile
and graphite due to the near normal grade distributions and adequate
variograms. Variography analysis was used to determine population nugget
effect and OK search and neighbourhood parameters.
Each grade domain was treated as a 2D seam and estimated using OK with dynamic
anisotropy which followed the broad mineralisation continuity trends. No
declustering or removal of twin data was required, as OK is an optimal
declustering algorithm, and the post OK checks demonstrated no negative
weights in the mineralised zones. Any areas not estimated were set to waste
grades.
The availability of check estimates, previous estimates and/or mine production This is the fifth MRE for the Kasiya Deposit.
records and whether the Mineral Resource estimate takes appropriate account of
such data. Bulk-scale test work has been completed and results support the view of the
Competent Person that an economic deposit of readily separable, high- quality
rutile is anticipated from the Kasiya Deposit. The recovery of a coarse- flake
graphite by-product was also achieved by the test work.
The assumptions made regarding recovery of by-products. A graphite co-product was modelled as recoverable TGC based on the test-work.
Estimation of deleterious elements or other non-grade variables of economic No significant deleterious elements are identified. A selection of assay,
significance (e.g. sulphur for acid mine drainage characterisation). magnetic separation, XRF and mineralogical results have been reviewed.
In the case of block model interpolation, the block size in relation to the The parent cell size used is equivalent to the infill drill hole spacing
average sample spacing and the search employed. within the Measured Resource (200m*200m). XY sub-celling to 50m*50m is
adequate resolution for horizontal boundaries. Seam modelling ensured the
weathering and topography layers were vertically accurate (within the 50m
horizontal resolution). Grade was estimated using the parent cell panel size.
Any assumptions behind modelling of selective mining units. Dry mining using bulk mining methods such as dragline and/or excavator load
and haul has been considered in the modelling. The assumption is that any
mining selectivity will be based on distinct weathering horizons which range
in thickness from 2m to 9m, with a near horizontal dip.
Any assumptions about correlation between variables. Rutile and graphite mineralisation have been modelled separately as there is
no correlation between them.
Description of how the geological interpretation was used to control the Grade estimation was constrained by hard boundaries (domains) that result from
resource estimates. the geological interpretation and mineralisation interpretation.
Discussion of basis for using or not using grade cutting or capping. Top Capping was applied to the composites considered to be outliers to reduce
local high-grade bias. Generally <1% of samples had a grade cap applied.
The process of validation, the checking process used, the comparison of model Validation of the grade estimate was completed both visually and
data to drill hole data, and use of reconciliation data if available. statistically.
Visual validation by loading the model and drill hole files and annotating,
colouring and using filtering to check for the appropriateness of the
estimate.
Distributions of section line averages (swath plots) for drill holes and
models were prepared for each zone and orientation for comparison purposes.
The resource model has appropriately averaged informing drill hole data and is
considered suitable to support the resource classifications as applied to the
estimate.
No production has been carried out, so no reconciliation data is available.
Moisture Whether the tonnages are estimated on a dry basis or with natural moisture, Tonnages are estimated on a dry basis. Average moisture content is included in
and the method of determination of the moisture content. the model for mine planning purposes.
Cut-off parameters The basis of the adopted cut-off grade(s) or quality parameters applied. The mineral resource is confined to an economically optimised pit shell based
on financial parameters.
For clarity and comparison with previous resource estimates, the MRE has been
subdivided into a rutile dominant resource (reported at >=0.4% Rutile which
is similar to previous MRE's) and a graphite rich zone (generally below the
rutile resource) reported at 0.6% TGC cutoff grade.
Note: The pit shell includes internal lower grade rutile and graphite material
which is tabled for transparency as it will most probably be mined due to the
bulk mining methodology.
Mining factors or assumptions Assumptions made regarding possible mining methods, minimum mining dimensions Dry-mining has been determined as the optimal method of mining for the Kasiya
and internal (or, if applicable, external) mining dilution. It is always Rutile deposit. The materials competence is loose, soft, fine and friable with
necessary as part of the process of determining reasonable prospects for no cemented sand or dense clay layers, allowing for a free dig mining method.
eventual economic extraction to consider potential mining methods, but the It is considered that the strip ratio would be zero or near zero.
assumptions made regarding mining methods and parameters when estimating
Mineral Resources may not always be rigorous. Where this is the case, this Dilution is considered to be minimal as rutile mineralisation occurs from
should be reported with an explanation of the basis of the mining assumptions surface and mineralisation is generally gradational into the low-grade
made. portions with few sharp boundaries.
Metallurgical factors or assumptions The basis for assumptions or predictions regarding metallurgical amenability. Recovery parameters have not been factored into the estimate. However, the
It is always necessary as part of the process of determining reasonable valuable minerals are readily separable due to their SG differential and are
prospects for eventual economic extraction to consider potential metallurgical expected to have a high recovery through the proposed, conventional wet
methods, but the assumptions regarding metallurgical treatment processes and concentration plant.
parameters made when reporting Mineral Resources may not always be rigorous.
Where this is the case, this should be reported with an explanation of the Rigorous metallurgical testwork on rutile and graphite recoverability and
basis of the metallurgical assumptions made. specifications has been completed on numerous bulk samples since 2018.
Rutile recovered to product is modelled at 97.6% (the estimated rutile grade
is a recovered grade).
The average recovery for graphite recovered to product is 70.4%.
The chemical and physical specifications of both products rank in the top
quartile.
Environmental factors or assumptions Assumptions made regarding possible waste and process residue disposal The Project has commenced preparation of the Environmental and Social Impact
options. It is always necessary as part of the process of determining Assessment (ESIA), and all supporting biological, social and biophysical
reasonable prospects for eventual economic extraction to consider the specialist studies have been concluded, and have been fed into the Project
potential environmental impacts of the mining and processing operation. While design as modifying factors or assumptions.
at this stage the determination of potential environmental impacts,
particularly for a greenfields project, may not always be well advanced, the The unconstrained MRE was constrained by both environmental and social no-go
status of early consideration of these potential environmental impacts should areas which acted as modifying factors. This allowed the determination of the
be reported. Where these aspects have not been considered this should be constrained MRE covering the current 22 pits of 3,400 hectares. The
reported with an explanation of the environmental assumptions made. constrained mapping reduced social impact by completely avoiding nearby
communities, as well as avoiding all remanent natural habitats - barring the
establishment of the Water Storage Dam.
With respect to possible waste and process residue, full hydrogeological and
geochemical testing has been concluded. Metals leaching is deemed a low risk,
with most modelled parameters are expected to remain within local and WHO
drinking water standards. Risk related to acid mine drainage has been
categorized as intermediate - as while the Sulphides are below thresholds
(<0.3%) there is near no neutralizing capacity. Long-term kinetic leach
testing is required to verify the models; however, no specific or targeted
disposal measures is currently required as the risks is not deemed to be
material.
Bulk density Whether assumed or determined. If assumed, the basis for the assumptions. If In-situ dry bulk density was calculated from 400 core samples taken from
determined, the method used, whether wet or dry, the frequency of the spatially and lithologically-representative sites across the deposit.
measurements, the nature, size and representativeness of the samples.
Dry bulk density is calculated from PT drill core using a cylinder volume wet
and dry method performed by Sovereign in Malawi.
Shelby tube core samples collected from the 2024 PTDD drill program were
analysed by CIVILAB in South Africa.
Bulk density data was coded by weathering horizon. Population distributions
were then reviewed and obvious outlies removed. Either the mean or median were
used as the average for each weathering and/or rock type domain.
The bulk density for bulk material must have been measured by methods that The in-situ volume and dry mass method was used, which accounts for porosity.
adequately account for void spaces (vughs, porosity, etc.), moisture and
differences between rock and alteration zones within the deposit. No significant voids are expected.
Discuss assumptions for bulk density estimates used in the evaluation process The average in-situ dry bulk density of the total MRE is 1.60 t/m3.
of the different materials.
This is derived from using an average density of 1.39 t/m3 for the SOIL; 1.58
t/m3 for the FERP, 1.66 t/m3 for the MOTT; 1.68 t/m3 for the PSAP; and 1.77
t/m3 for SAPL; Density was assigned based on the weathering domain.
Classification The basis for the classification of the Mineral Resources into varying The Kasiya MRE has been classified as Measured, Indicated or Inferred.
confidence categories.
JORC classification considered geological understanding; mineralisation
continuity; drilling and sampling quality and spacing; OK estimation
efficiency and confidence (SoR); and proposed mining method and scale.
The dominant control on grade distribution within the mineralised zone is
intensity of weathering. Rutile is a mineral resistant to weathering and is
concentrated by depletion of less resistant minerals during the weathering
process resulting in higher grades near the surface where more intense
weathering has taken place. The weathering profiles are consistent and readily
defined by logging of drill samples.
Both rutile and graphite mineralisation have been well defined by drilling and
appropriate sample analysis to determine rutile recovered grade and in-situ
TGC. Both mineralisation zones are broad and continuous with rutile dominant
in the Soil, FERP and MOTT horizons, and graphite in the PSAP and SAPL
horizons. There is significant overlap of the two mineralisation zones. The
mineralisation is truncated either by changes in the protolith of displaced by
mafic intrusives. Recent drainage has also impacted mineralisation continuity.
The dominant zones of mineralisation exceed 10km of strike continuity and
range from 1 to 4km in width.
Regional exploration was completed on a nominal 800m square grid, with infill
to 400m then either 200m square or 200m offset grid.
Twin holes plus some close spaced geostatistical drilling, close spaced
channel sampling during the trial mining and open pit sampling have all
demonstrated the robustness of the geology interpretation and mineralisation
continuity.
OK efficiency (KE) generally exceeds 0.6 with SoR exceeding 0.85 in the
dominant mineralised zones.
On the basis of the high confidence geology interpretation; mineralisation
scale and continuity, including taking into account the bulk mining method;
and very tight grade distributions within the estimation domains the Competent
Person is comfortable classifying all of the Mineral Resource as either
Measured, Indicated or Inferred.
Measured was defined using a nominal KE >=0.6 and a SOR >=0.85 but
generally exceeding 0.9, which generally fits areas with a nominal drill
spacing of 200 by 200m. A boundary was used to define the Measured Mineral
Resource.
Indicated was defined using a nominal KE >=0.4 to 0.5 and a SOR >=0.8,
which generally fits areas with a nominal drill spacing of 400 to 200m. A
boundary was used to define the Indicated Mineral Resource.
The Mineral Resource was constrained to a potentially economic open pit shell
to reflect the code requirement for Reasonable Prospects of Eventual Economic
Extraction (RPEEE). The shell was defined using Whittle Open Pit Optimisation
with the following parameters:
Rutile: Net concentrate revenue US$1400/t; Process recovery 100%;
Graphite: Net revenue US$1200/t ; Average Process recovery of 70.4%.
Mining OPEX US$1.35/t; Process OPEX US$5.44/t
The MRE is presented in 3 Tables.
The top table presents the rutile dominant mineral resource based on a higher
rutile cut-off pit shell - optimised using the $1,400 rutile price using a
nominal ore grade cutoff of 0.75% Rutile. This pit shell was generated to
maximise material above 0.7% Rutile as a comparison with the previously
reported MRE.
The middle table presents the remaining mineral resource within the primary
pit shell but outside (mainly below) the rutile dominant pit shell. This table
is further sub-divided to show the high grade graphite material (primarily at
depth) and the lower grade rutile material (primarily at the edges of the
deposit).
The bottom table presents the entire MRE constrained to the RPEEE Open Pit
shell. No cutoff is applied as material <0.7% Rut_EQ will likely be mined
as internal dilution as it is spread throughout the MRE in small pockets not
suitable for selective mining.
Whether appropriate account has been taken of all relevant factors (i.e. All relevant factors were assessed by the Competent Person, including data
relative confidence in tonnage/grade estimations, reliability of input data, quality, confidence in the geological interpretation and framework for the
confidence in continuity of geology and metal values, quality, quantity and mineral resource, mineralisation continuity and variability. Geostatistical
distribution of the data). parameters relative to drillhole spacing was used guide the classification of
the Mineral Resource.
Whether the result appropriately reflects the Competent Person's view of the The MRE appropriately reflects the Competent Person's view of the Kasiya
deposit rutile and graphite deposit.
Audits or reviews The results of any audits or reviews of Mineral Resource estimates. The Mineral Resource was completed by the SVM technical services team. MSA
completed fine tuning of the mineralisation interpretation, statistics,
variography and OK parameters. The final model was reviewed by the Competent
Person within the MSA team.
Discussion of relative accuracy/ confidence Where appropriate a statement of the relative accuracy and confidence level in Additional mineralisation is expected to occur below the effective depth of HA
the Mineral Resource estimate using an approach or procedure deemed and PT drilling. This has been confirmed by areas which have included deeper
appropriate by the Competent Person. For example, the application of AC drilling.
statistical or geostatistical procedures to quantify the relative accuracy of
the resource within stated confidence limits, or, if such an approach is not A high-degree of uniformity exists in the broad and contiguous lithological
deemed appropriate, a qualitative discussion of the factors that could affect and grade character of the deposit. Drilling, sampling and data collection
the relative accuracy and confidence of the estimate. procedures have been professionally executed. QA protocols and interpretations
conform to industry best practice.
Assay, mineralogical determinations and metallurgical test work conform to
industry best practice and demonstrate a rigorous assessment of product and
procedure. The development of a conventional processing flowsheet and
marketability studies support the classification of the Kasiya Resource.
The statement should specify whether it relates to global or local estimates, The block model estimate is of sufficient accuracy to apply modifying factors
and, if local, state the relevant tonnages, which should be relevant to for mine planning in the portion classified as Measured and Indicated Mineral
technical and economic evaluation. Documentation should include assumptions Resources.
made and the procedures used.
Inferred Mineral Resources are global in nature and are suitable for economic
evaluation at a high level such as a scoping study.
Recoverable resource estimates have not been made on a selective mining unit
basis.
These statements of relative accuracy and confidence of the estimate should be No production data are available to reconcile model results.
compared with production data, where available.
Additional sampling included open pits, channel sampling of the trial mining
area which were used for checking and validation of the various drilling
methods:
HTYPE_4 Num Holes Metres Drilled
CH 54 315.0
CL 10 40.0
HACL 279 829.6
PIT 87 400.3
RC 9 279.0
PC 17 91.4
Total 456 1,955.3
Site visits
Comment on any site visits undertaken by the Competent Person and the outcome
of those visits.
Field and SSL laboratory visits were completed over a 1-week period in
November 2024 and June 2025. A high standard of operation, procedure and
personnel was observed and reported.
If no site visits have been undertaken indicate why this is the case.
Not applicable
Geological interpretation
Confidence in (or conversely, the uncertainty of) the geological
interpretation of the mineral deposit.
There is a high degree of repeatability and uniformity in the geological
character of the Kasiya Deposit demonstrated by lithological logging of AC, PT
core and HA samples. Satellite imagery and airborne geophysical data provided
guidance for interpreting the strike continuity of the deposit.
Drill hole intercept logging and assay results (AC, PT, SA and HA),
stratigraphic interpretations from drill core and geological logs of drill
data have formed the basis for the geological interpretation. The drilling
exclusively targeted the SOIL, FERP, MOTT and SAPL weathering horizons, with
no sampling of the SAPR and below the upper level of the fresh rock (FRESH)
domain.
Nature of the data used and of any assumptions made.
No assumptions were made.
The effect, if any, of alternative interpretations on Mineral Resource
estimation.
No alternative interpretations on Mineral Resource Estimation are offered.
The use of geology in guiding and controlling Mineral Resource estimation.
The mineral resource is constrained by the drill array plus up to 400m area of
influence from nearest drilling.
The topographical DTM constrains the vertical extent of the resource.
The primary domain control is weathering type - SOIL+FERP, MOTT, PSAP and
SAPL. This is further sub-divided into rutile mineralisation (nominally
>=0.5% Rutile) and graphite mineralisation (nominally >=0.6% TGC). The
mineralisation domains are treated independently of each other.
The base to mineralisation is constrained by a DTM representing the bottom of
drilling.
AC drilling has accurately defined depth to basement at the saprock interface,
which has been modelled in the MRE where intersected.
The factors affecting continuity both of grade and geology.
Rutile grade is generally concentrated in surface regolith horizons. Deposit
stratigraphy and weathering is consistent along and across strike. Rutile
grade trend is oriented at 45 degrees at Kasiya North and 360 degrees at
Kasiya South and far North, which mimics the underlying basement source rocks
and residual topography. Rutile varies across strike as a result of the
layering of mineralised and non-mineralised basement rocks.
Areas containing near surface clay lenses, amphibolite and narrow cross
striking pegmatitic rocks are barren of rutile and graphite. These zones have
been modelled and excluded from the mineralisation domains.
Dimensions
The extent and variability of the Mineral Resource expressed as length (along
strike or otherwise), plan width, and depth below surface to the upper and
lower limits of the Mineral Resource.
The Kasiya mineralised footprint strikes N - S & NE - SW, is 72km long and
approximately 20km at its widest section. The currently defined surface extent
of >=0.7% rutile is about 268.6km2.
The mineral resource occurs from surface to the saprolite-saprock interface,
which is typically in the order of 15m, although can attain localised
thicknesses in excess of 25m. The deposit thins towards the edges to
approximately 5m and pinches out in the drainage channels.
Estimation and modelling techniques
The nature and appropriateness of the estimation technique(s) applied and key
assumptions, including treatment of extreme grade values, domaining,
interpolation parameters and maximum distance of extrapolation from data
points. If a computer assisted estimation method was chosen include a
description of computer software and parameters used.
Datamine Studio RM, LeapFrog and Supervisor software are used for the data
analysis, variography, geological interpretation and resource estimation.
A 3D block model honouring the geology boundaries which included weathering
horizons; barren mafic intrusives; surface clay horizons, cross striking
pegmatitic zones and presence of barren or low grade amphibolite was created.
The model was also coded with the tenement EL codes, rock in-situ dry bulk
density and moisture content.
Rutile mineralisation was defined as the last intercept >=2m down hole
exceeding 0.5% Rutile. As a general rule, rutile grade is highest at the
surface gradually reducing in grade with depth. Using this guideline very
little internal low grade/waste is introduced. The resulting sample point data
was used to create the bounding lower surface for a rutile mineralisation DTM.
Additional manual points were interpreted in section by section to ensure
consistency, especially in areas with wider spaced drilling.
Graphite mineralisation was defined as the highest up hole intercept >-2m
exceeding 0.6% TGC. As a general rule TGC grade is highest at depth gradually
reducing in grade closer to the surface. Using this guideline very little
internal low grade/waste is introduced. Similarly to rutile, a graphite
mineralisation upper limit DTM was constructed. The lower limit of graphite
mineralisation was either the base of drilling or the top of SAPR if drilling
intersected SAPR.
Eight grade domains were created, 4 mineralised and 4 low grade / waste for
both rutile and graphite, based on the combination of weathering type inside
or outside the mineralisation DTM's. Samples were composited to 1 sample per
drillhole per domain. Rutile and TGC samples were treated independently as
there is no correlation between rutile and TGC grades.
The composite populations generally approximated normal distributions with
some -ve and/or +ve skewness relating to the imposed mineralisation boundary.
Ordinary Kriging (OK) was considered the best grade estimator for both rutile
and graphite due to the near normal grade distributions and adequate
variograms. Variography analysis was used to determine population nugget
effect and OK search and neighbourhood parameters.
Each grade domain was treated as a 2D seam and estimated using OK with dynamic
anisotropy which followed the broad mineralisation continuity trends. No
declustering or removal of twin data was required, as OK is an optimal
declustering algorithm, and the post OK checks demonstrated no negative
weights in the mineralised zones. Any areas not estimated were set to waste
grades.
The availability of check estimates, previous estimates and/or mine production
records and whether the Mineral Resource estimate takes appropriate account of
such data.
This is the fifth MRE for the Kasiya Deposit.
Bulk-scale test work has been completed and results support the view of the
Competent Person that an economic deposit of readily separable, high- quality
rutile is anticipated from the Kasiya Deposit. The recovery of a coarse- flake
graphite by-product was also achieved by the test work.
The assumptions made regarding recovery of by-products.
A graphite co-product was modelled as recoverable TGC based on the test-work.
Estimation of deleterious elements or other non-grade variables of economic
significance (e.g. sulphur for acid mine drainage characterisation).
No significant deleterious elements are identified. A selection of assay,
magnetic separation, XRF and mineralogical results have been reviewed.
In the case of block model interpolation, the block size in relation to the
average sample spacing and the search employed.
The parent cell size used is equivalent to the infill drill hole spacing
within the Measured Resource (200m*200m). XY sub-celling to 50m*50m is
adequate resolution for horizontal boundaries. Seam modelling ensured the
weathering and topography layers were vertically accurate (within the 50m
horizontal resolution). Grade was estimated using the parent cell panel size.
Any assumptions behind modelling of selective mining units.
Dry mining using bulk mining methods such as dragline and/or excavator load
and haul has been considered in the modelling. The assumption is that any
mining selectivity will be based on distinct weathering horizons which range
in thickness from 2m to 9m, with a near horizontal dip.
Any assumptions about correlation between variables.
Rutile and graphite mineralisation have been modelled separately as there is
no correlation between them.
Description of how the geological interpretation was used to control the
resource estimates.
Grade estimation was constrained by hard boundaries (domains) that result from
the geological interpretation and mineralisation interpretation.
Discussion of basis for using or not using grade cutting or capping.
Top Capping was applied to the composites considered to be outliers to reduce
local high-grade bias. Generally <1% of samples had a grade cap applied.
The process of validation, the checking process used, the comparison of model
data to drill hole data, and use of reconciliation data if available.
Validation of the grade estimate was completed both visually and
statistically.
Visual validation by loading the model and drill hole files and annotating,
colouring and using filtering to check for the appropriateness of the
estimate.
Distributions of section line averages (swath plots) for drill holes and
models were prepared for each zone and orientation for comparison purposes.
The resource model has appropriately averaged informing drill hole data and is
considered suitable to support the resource classifications as applied to the
estimate.
No production has been carried out, so no reconciliation data is available.
Moisture
Whether the tonnages are estimated on a dry basis or with natural moisture,
and the method of determination of the moisture content.
Tonnages are estimated on a dry basis. Average moisture content is included in
the model for mine planning purposes.
Cut-off parameters
The basis of the adopted cut-off grade(s) or quality parameters applied.
The mineral resource is confined to an economically optimised pit shell based
on financial parameters.
For clarity and comparison with previous resource estimates, the MRE has been
subdivided into a rutile dominant resource (reported at >=0.4% Rutile which
is similar to previous MRE's) and a graphite rich zone (generally below the
rutile resource) reported at 0.6% TGC cutoff grade.
Note: The pit shell includes internal lower grade rutile and graphite material
which is tabled for transparency as it will most probably be mined due to the
bulk mining methodology.
Mining factors or assumptions
Assumptions made regarding possible mining methods, minimum mining dimensions
and internal (or, if applicable, external) mining dilution. It is always
necessary as part of the process of determining reasonable prospects for
eventual economic extraction to consider potential mining methods, but the
assumptions made regarding mining methods and parameters when estimating
Mineral Resources may not always be rigorous. Where this is the case, this
should be reported with an explanation of the basis of the mining assumptions
made.
Dry-mining has been determined as the optimal method of mining for the Kasiya
Rutile deposit. The materials competence is loose, soft, fine and friable with
no cemented sand or dense clay layers, allowing for a free dig mining method.
It is considered that the strip ratio would be zero or near zero.
Dilution is considered to be minimal as rutile mineralisation occurs from
surface and mineralisation is generally gradational into the low-grade
portions with few sharp boundaries.
Metallurgical factors or assumptions
The basis for assumptions or predictions regarding metallurgical amenability.
It is always necessary as part of the process of determining reasonable
prospects for eventual economic extraction to consider potential metallurgical
methods, but the assumptions regarding metallurgical treatment processes and
parameters made when reporting Mineral Resources may not always be rigorous.
Where this is the case, this should be reported with an explanation of the
basis of the metallurgical assumptions made.
Recovery parameters have not been factored into the estimate. However, the
valuable minerals are readily separable due to their SG differential and are
expected to have a high recovery through the proposed, conventional wet
concentration plant.
Rigorous metallurgical testwork on rutile and graphite recoverability and
specifications has been completed on numerous bulk samples since 2018.
Rutile recovered to product is modelled at 97.6% (the estimated rutile grade
is a recovered grade).
The average recovery for graphite recovered to product is 70.4%.
The chemical and physical specifications of both products rank in the top
quartile.
Environmental factors or assumptions
Assumptions made regarding possible waste and process residue disposal
options. It is always necessary as part of the process of determining
reasonable prospects for eventual economic extraction to consider the
potential environmental impacts of the mining and processing operation. While
at this stage the determination of potential environmental impacts,
particularly for a greenfields project, may not always be well advanced, the
status of early consideration of these potential environmental impacts should
be reported. Where these aspects have not been considered this should be
reported with an explanation of the environmental assumptions made.
The Project has commenced preparation of the Environmental and Social Impact
Assessment (ESIA), and all supporting biological, social and biophysical
specialist studies have been concluded, and have been fed into the Project
design as modifying factors or assumptions.
The unconstrained MRE was constrained by both environmental and social no-go
areas which acted as modifying factors. This allowed the determination of the
constrained MRE covering the current 22 pits of 3,400 hectares. The
constrained mapping reduced social impact by completely avoiding nearby
communities, as well as avoiding all remanent natural habitats - barring the
establishment of the Water Storage Dam.
With respect to possible waste and process residue, full hydrogeological and
geochemical testing has been concluded. Metals leaching is deemed a low risk,
with most modelled parameters are expected to remain within local and WHO
drinking water standards. Risk related to acid mine drainage has been
categorized as intermediate - as while the Sulphides are below thresholds
(<0.3%) there is near no neutralizing capacity. Long-term kinetic leach
testing is required to verify the models; however, no specific or targeted
disposal measures is currently required as the risks is not deemed to be
material.
Bulk density
Whether assumed or determined. If assumed, the basis for the assumptions. If
determined, the method used, whether wet or dry, the frequency of the
measurements, the nature, size and representativeness of the samples.
In-situ dry bulk density was calculated from 400 core samples taken from
spatially and lithologically-representative sites across the deposit.
Dry bulk density is calculated from PT drill core using a cylinder volume wet
and dry method performed by Sovereign in Malawi.
Shelby tube core samples collected from the 2024 PTDD drill program were
analysed by CIVILAB in South Africa.
Bulk density data was coded by weathering horizon. Population distributions
were then reviewed and obvious outlies removed. Either the mean or median were
used as the average for each weathering and/or rock type domain.
The bulk density for bulk material must have been measured by methods that
adequately account for void spaces (vughs, porosity, etc.), moisture and
differences between rock and alteration zones within the deposit.
The in-situ volume and dry mass method was used, which accounts for porosity.
No significant voids are expected.
Discuss assumptions for bulk density estimates used in the evaluation process
of the different materials.
The average in-situ dry bulk density of the total MRE is 1.60 t/m3.
This is derived from using an average density of 1.39 t/m3 for the SOIL; 1.58
t/m3 for the FERP, 1.66 t/m3 for the MOTT; 1.68 t/m3 for the PSAP; and 1.77
t/m3 for SAPL; Density was assigned based on the weathering domain.
Classification
The basis for the classification of the Mineral Resources into varying
confidence categories.
The Kasiya MRE has been classified as Measured, Indicated or Inferred.
JORC classification considered geological understanding; mineralisation
continuity; drilling and sampling quality and spacing; OK estimation
efficiency and confidence (SoR); and proposed mining method and scale.
The dominant control on grade distribution within the mineralised zone is
intensity of weathering. Rutile is a mineral resistant to weathering and is
concentrated by depletion of less resistant minerals during the weathering
process resulting in higher grades near the surface where more intense
weathering has taken place. The weathering profiles are consistent and readily
defined by logging of drill samples.
Both rutile and graphite mineralisation have been well defined by drilling and
appropriate sample analysis to determine rutile recovered grade and in-situ
TGC. Both mineralisation zones are broad and continuous with rutile dominant
in the Soil, FERP and MOTT horizons, and graphite in the PSAP and SAPL
horizons. There is significant overlap of the two mineralisation zones. The
mineralisation is truncated either by changes in the protolith of displaced by
mafic intrusives. Recent drainage has also impacted mineralisation continuity.
The dominant zones of mineralisation exceed 10km of strike continuity and
range from 1 to 4km in width.
Regional exploration was completed on a nominal 800m square grid, with infill
to 400m then either 200m square or 200m offset grid.
Twin holes plus some close spaced geostatistical drilling, close spaced
channel sampling during the trial mining and open pit sampling have all
demonstrated the robustness of the geology interpretation and mineralisation
continuity.
OK efficiency (KE) generally exceeds 0.6 with SoR exceeding 0.85 in the
dominant mineralised zones.
On the basis of the high confidence geology interpretation; mineralisation
scale and continuity, including taking into account the bulk mining method;
and very tight grade distributions within the estimation domains the Competent
Person is comfortable classifying all of the Mineral Resource as either
Measured, Indicated or Inferred.
Measured was defined using a nominal KE >=0.6 and a SOR >=0.85 but
generally exceeding 0.9, which generally fits areas with a nominal drill
spacing of 200 by 200m. A boundary was used to define the Measured Mineral
Resource.
Indicated was defined using a nominal KE >=0.4 to 0.5 and a SOR >=0.8,
which generally fits areas with a nominal drill spacing of 400 to 200m. A
boundary was used to define the Indicated Mineral Resource.
The Mineral Resource was constrained to a potentially economic open pit shell
to reflect the code requirement for Reasonable Prospects of Eventual Economic
Extraction (RPEEE). The shell was defined using Whittle Open Pit Optimisation
with the following parameters:
Rutile: Net concentrate revenue US$1400/t; Process recovery 100%;
Graphite: Net revenue US$1200/t ; Average Process recovery of 70.4%.
Mining OPEX US$1.35/t; Process OPEX US$5.44/t
The MRE is presented in 3 Tables.
The top table presents the rutile dominant mineral resource based on a higher
rutile cut-off pit shell - optimised using the $1,400 rutile price using a
nominal ore grade cutoff of 0.75% Rutile. This pit shell was generated to
maximise material above 0.7% Rutile as a comparison with the previously
reported MRE.
The middle table presents the remaining mineral resource within the primary
pit shell but outside (mainly below) the rutile dominant pit shell. This table
is further sub-divided to show the high grade graphite material (primarily at
depth) and the lower grade rutile material (primarily at the edges of the
deposit).
The bottom table presents the entire MRE constrained to the RPEEE Open Pit
shell. No cutoff is applied as material <0.7% Rut_EQ will likely be mined
as internal dilution as it is spread throughout the MRE in small pockets not
suitable for selective mining.
Whether appropriate account has been taken of all relevant factors (i.e.
relative confidence in tonnage/grade estimations, reliability of input data,
confidence in continuity of geology and metal values, quality, quantity and
distribution of the data).
All relevant factors were assessed by the Competent Person, including data
quality, confidence in the geological interpretation and framework for the
mineral resource, mineralisation continuity and variability. Geostatistical
parameters relative to drillhole spacing was used guide the classification of
the Mineral Resource.
Whether the result appropriately reflects the Competent Person's view of the
deposit
The MRE appropriately reflects the Competent Person's view of the Kasiya
rutile and graphite deposit.
Audits or reviews
The results of any audits or reviews of Mineral Resource estimates.
The Mineral Resource was completed by the SVM technical services team. MSA
completed fine tuning of the mineralisation interpretation, statistics,
variography and OK parameters. The final model was reviewed by the Competent
Person within the MSA team.
Discussion of relative accuracy/ confidence
Where appropriate a statement of the relative accuracy and confidence level in
the Mineral Resource estimate using an approach or procedure deemed
appropriate by the Competent Person. For example, the application of
statistical or geostatistical procedures to quantify the relative accuracy of
the resource within stated confidence limits, or, if such an approach is not
deemed appropriate, a qualitative discussion of the factors that could affect
the relative accuracy and confidence of the estimate.
Additional mineralisation is expected to occur below the effective depth of HA
and PT drilling. This has been confirmed by areas which have included deeper
AC drilling.
A high-degree of uniformity exists in the broad and contiguous lithological
and grade character of the deposit. Drilling, sampling and data collection
procedures have been professionally executed. QA protocols and interpretations
conform to industry best practice.
Assay, mineralogical determinations and metallurgical test work conform to
industry best practice and demonstrate a rigorous assessment of product and
procedure. The development of a conventional processing flowsheet and
marketability studies support the classification of the Kasiya Resource.
The statement should specify whether it relates to global or local estimates,
and, if local, state the relevant tonnages, which should be relevant to
technical and economic evaluation. Documentation should include assumptions
made and the procedures used.
The block model estimate is of sufficient accuracy to apply modifying factors
for mine planning in the portion classified as Measured and Indicated Mineral
Resources.
Inferred Mineral Resources are global in nature and are suitable for economic
evaluation at a high level such as a scoping study.
Recoverable resource estimates have not been made on a selective mining unit
basis.
These statements of relative accuracy and confidence of the estimate should be
compared with production data, where available.
No production data are available to reconcile model results.
APPENDIX 2: DRILL RESULTS
Plan View of drillhole collars showing drillholes not previously announced and
used in the MRE update coloured in black, red are all collars, grey outline
are current SVM tenements
Drillhole From To Length Rutile % TGC % Easting Northing
CHHA0002 0.0 4.0 4.0 1.27 0.01 560453.0 8518542.1
CHHA0005 0.0 4.0 4.0 0.88 1.20 559647.0 8517013.1
CHHA0006 0.0 8.0 8.0 1.00 0.42 560398.0 8516694.3
CHHA0007 0.0 2.0 2.0 0.77 0.20 561175.7 8516477.8
CHHA0008 0.0 6.0 6.0 1.43 0.70 561964.6 8516377.0
CHHA0010 0.0 3.0 3.0 0.72 0.60 567400.1 8513371.3
CHHA0011 0.0 2.0 2.0 1.09 0.01 567800.2 8513375.4
CHHA0011 9.0 11.0 2.0 0.71 4.30 567800.2 8513375.4
CHHA0012 0.0 5.0 5.0 0.79 0.01 568199.3 8513401.2
CHHA0013 0.0 4.0 4.0 0.81 0.40 568598.5 8513399.1
CHHA0014 0.0 5.0 5.0 0.82 0.10 568599.6 8510403.1
CHHA0016 0.0 5.0 5.0 0.90 0.30 567800.2 8510377.5
CHHA0017 0.0 5.0 5.0 0.87 0.60 566984.4 8510406.3
CHHA0018 0.0 13.0 13.0 1.09 1.10 567397.1 8510378.3
CHHA0019 0.0 2.0 2.0 0.77 0.01 566998.2 8506402.4
CHHA0020 0.0 12.0 12.0 0.74 0.59 567363.0 8506409.9
CHHA0021 0.0 5.0 5.0 0.84 0.10 567804.2 8506431.6
CHHA0024 0.0 3.0 3.0 0.84 0.01 566999.2 8504802.2
CHHA0025 0.0 11.0 11.0 1.12 1.53 567409.1 8504791.2
CHHA0026 0.0 3.0 3.0 1.27 0.40 567801.6 8504799.8
CHHA0027 0.0 3.0 3.0 0.70 0.01 568189.6 8504804.4
CHHA0028 0.0 6.0 6.0 0.79 1.15 569000.0 8504800.2
CHHA0029 0.0 4.0 4.0 0.77 0.20 569401.5 8504800.8
CHHA0030 9.0 13.0 4.0 0.71 2.60 569800.2 8504799.9
CHHA0032 0.0 12.0 12.0 1.23 3.32 569002.8 8503588.0
CHHA0037 0.0 4.0 4.0 1.15 0.01 570995.9 8503603.1
CHHA0038 0.0 4.0 4.0 1.06 0.01 570602.5 8503607.4
CHHA0040 0.0 3.0 3.0 0.82 1.60 569784.1 8503615.6
CHHA0041 0.0 12.0 12.0 0.97 3.60 569390.4 8503587.9
CHHA0042 0.0 14.0 14.0 0.78 1.89 567396.1 8502383.9
CHHA0043 0.0 10.0 10.0 0.89 1.68 567801.7 8502369.0
CHHA0044 0.0 13.0 13.0 0.94 2.18 568200.4 8502398.9
KYAC0021 0.0 12.0 12.0 1.05 2.25 544800.7 8471800.0
KYAC0041 0.0 3.0 3.0 1.18 0.01 544600.7 8472199.8
KYAC0063 0.0 23.0 23.0 0.98 1.20 543400.6 8471399.5
KYAC0083 0.0 18.0 18.0 0.98 1.54 543952.7 8468998.7
KYAC0103 0.0 27.0 27.0 1.08 2.11 549800.5 8479402.3
KYAC0123 0.0 29.0 29.0 1.16 1.75 548599.5 8478398.7
KYAC0143 0.0 25.5 25.5 1.00 2.06 544000.2 8468000.2
KYAC0163 0.0 5.0 5.0 1.16 0.30 545600.2 8464999.3
KYAC0163 27.0 29.0 2.0 0.78 3.90 545600.2 8464999.3
KYAC0183 0.0 2.0 2.0 1.24 0.01 546198.2 8467998.6
KYAC0183 8.0 16.0 8.0 0.92 4.15 546198.2 8467998.6
KYAC0479 8.0 20.0 12.0 1.05 543498.6 8471501.6
KYAC0480 8.0 16.0 8.0 0.98 543299.0 8472101.2
KYAC0481 8.0 10.0 2.0 0.72 544299.4 8471700.0
KYAC0482 8.0 18.0 10.0 0.88 544700.5 8472099.3
KYAC0483 8.0 20.0 12.0 0.87 543200.1 8470200.4
KYAC0484 8.0 16.0 8.0 0.82 543100.4 8469900.9
KYAC0485 6.0 8.0 2.0 0.82 543399.8 8469600.7
KYAC0486 8.0 10.0 2.0 1.04 543900.2 8468101.0
KYAC0486 16.0 20.0 4.0 0.77 543900.2 8468101.0
KYAC0487 8.0 20.0 12.0 0.92 544499.8 8468699.0
KYAC0488 4.0 19.0 15.0 1.41 7.19 544900.2 8472099.1
KYAC0489 6.0 12.0 6.0 0.75 1.90 544800.2 8472200.9
KYAC0490 10.0 16.0 6.0 1.16 3.93 544900.5 8472300.4
KYAC0492 4.0 10.0 6.0 0.70 4.43 545000.0 8472400.1
KYAC0493 4.0 6.0 2.0 0.90 2.40 544900.0 8472500.0
KYAC0496 6.0 10.0 4.0 0.90 2.30 544700.0 8472299.0
KYAC0499 4.0 6.0 2.0 1.11 2.00 544499.6 8472098.0
KYAC0500 4.0 18.0 14.0 0.85 3.29 543099.1 8472300.0
KYAC0501 2.0 18.0 16.0 0.76 2.49 543098.8 8472100.4
KYAC0502 2.0 20.0 18.0 0.85 1.54 542998.9 8472000.0
KYAC0503 4.0 6.0 2.0 0.78 3.40 542899.1 8472100.2
KYAC0505 4.0 22.0 18.0 0.94 3.13 543499.8 8472098.0
KYAC0506 4.0 26.5 22.5 1.03 1.94 543700.2 8472101.0
KYAC0507 4.0 13.6 9.6 1.14 2.54 543299.8 8471901.1
KYAC0508 4.0 8.0 4.0 0.91 1.20 543098.9 8471899.5
KYAC0509 6.0 18.1 12.1 1.01 2.40 543300.9 8472299.9
KYAC0510 12.0 23.8 11.8 0.86 2.44 544100.2 8472099.4
KYAC0512 6.0 8.0 2.0 0.75 2.20 544700.1 8468901.1
KYAC0513 6.0 10.0 4.0 1.40 4.95 544499.6 8468900.4
KYAC0514 6.0 18.0 12.0 0.87 2.42 544700.8 8468700.0
KYAC0514 26.0 28.0 2.0 0.72 1.70 544700.8 8468700.0
KYAC0515 6.0 18.0 12.0 0.77 2.12 544698.8 8468500.1
KYAC0516 6.0 18.0 12.0 0.99 2.17 544499.8 8468501.0
KYAC0517 6.0 16.0 10.0 1.01 2.78 544500.7 8468300.2
KYAC0518 8.0 18.0 10.0 1.04 4.20 544500.1 8468100.8
KYAC0519 4.0 18.0 14.0 1.05 2.50 544300.0 8468701.0
KYAC0520 4.0 18.0 14.0 0.97 2.20 544300.1 8468499.1
KYAC0521 4.0 16.0 12.0 0.82 3.67 544293.8 8468300.4
KYAC0522 6.0 25.0 19.0 1.00 1.94 544100.5 8468301.3
KYAC0523 4.0 18.0 14.0 0.92 4.29 544102.9 8468099.9
KYAC0524 4.0 22.0 18.0 0.85 1.42 544099.4 8468500.1
KYAC0525 2.0 18.0 16.0 1.13 2.54 543699.3 8468100.0
KYAC0526 6.0 20.0 14.0 0.86 2.10 543699.9 8467897.0
KYAC0527 8.0 10.0 2.0 0.85 4.70 543899.0 8467700.1
KYAC0528 6.0 10.0 4.0 1.02 0.85 544099.3 8467699.8
KYAC0529 6.0 20.0 14.0 0.74 2.96 544299.0 8467700.0
KYAC0531 10.0 22.0 12.0 0.82 2.52 544199.2 8467599.9
KYAC0533 6.0 8.0 2.0 0.71 0.80 544601.1 8467600.1
KYDD0001 0.0 10.0 10.0 1.08 1.03 544499.1 8467899.8
KYDD0001 11.0 16.0 5.0 1.06 1.84 544499.1 8467899.8
KYDD0002 0.0 6.0 6.0 0.80 2.00 543498.9 8468099.9
KYDD0003 0.0 8.0 8.0 1.14 1.05 543699.0 8467700.0
KYDD0003 9.0 22.0 13.0 0.89 1.72 543699.0 8467700.0
KYDD0004 0.0 17.0 17.0 1.03 3.53 544301.2 8468099.8
KYDD0005 0.0 19.0 19.0 0.92 2.02 543900.9 8467499.4
KYDD0006 0.0 4.0 4.0 0.93 0.13 544200.6 8466800.4
KYDD0007 0.0 15.0 15.0 1.23 1.64 544301.0 8466500.0
KYDD0008 0.0 20.0 20.0 0.96 3.45 543900.2 8466300.1
KYDD0009 0.0 5.0 5.0 1.55 0.20 545301.1 8465700.3
KYDD0010 0.0 23.0 23.0 0.90 1.21 545699.0 8465499.7
KYDD0011 0.0 4.0 4.0 1.44 0.23 545299.8 8465100.9
KYDD0011 9.0 12.0 3.0 0.95 1.53 545299.8 8465100.9
KYDD0011 16.0 18.0 2.0 0.78 1.40 545299.8 8465100.9
KYDD0012 0.0 3.0 3.0 0.98 0.14 546099.9 8464901.0
KYDD0013 0.0 3.0 3.0 1.66 0.10 544299.7 8472099.4
KYDD0013 11.0 16.0 5.0 0.89 1.56 544299.7 8472099.4
KYDD0014 0.0 19.3 19.3 1.12 1.06 543899.8 8471900.3
KYDD0015 0.0 9.0 9.0 1.62 6.37 544700.8 8471499.5
KYDD0015 10.0 22.0 12.0 0.99 3.63 544700.8 8471499.5
KYDD0016 0.0 2.0 2.0 1.75 0.20 543501.1 8472300.1
KYDD0016 7.0 17.0 10.0 0.82 1.24 543501.1 8472300.1
KYDD0018 0.0 11.0 11.0 1.29 1.49 543300.2 8471700.8
KYDD0018 17.0 19.0 2.0 0.78 0.95 543300.2 8471700.8
KYDD0019 0.0 18.0 18.0 0.82 1.58 543098.2 8471699.8
KYDD0020 0.0 3.0 3.0 1.50 0.17 542899.9 8470101.0
KYDD0021 0.0 3.0 3.0 1.70 0.17 543400.0 8470000.9
KYDD0021 4.0 6.0 2.0 0.93 0.76 543400.0 8470000.9
KYDD0022 0.0 7.0 7.0 1.06 0.73 543300.4 8469700.8
KYDD0022 8.0 21.1 13.1 0.90 1.68 543300.4 8469700.8
KYDD0023 0.0 6.0 6.0 0.76 2.32 544299.8 8470901.3
KYDD0024 0.0 12.0 12.0 0.90 0.50 543899.8 8470499.3
KYDD0024 13.0 21.2 8.2 0.77 1.56 543899.8 8470499.3
KYDD0025 0.0 1.0 1.0 2.27 0.60 543799.9 8470001.2
KYDD0025 2.0 9.0 7.0 0.91 1.52 543799.9 8470001.2
KYDD0025 10.0 17.0 7.0 0.93 1.66 543799.9 8470001.2
KYDD0026 0.0 2.0 2.0 1.24 0.45 543899.9 8469701.0
KYDD0026 6.0 21.0 15.0 0.89 2.86 543899.9 8469701.0
KYDD0027 0.0 15.0 15.0 1.09 1.68 544300.2 8468900.9
KYDD0028 0.0 25.0 25.0 0.85 2.72 546100.2 8467301.1
KYDD0029 0.0 6.0 6.0 1.10 2.72 546485.2 8467899.3
KYDD0030 0.0 14.0 14.0 0.95 5.38 546098.7 8467705.1
KYHA0023 0.0 10.0 10.0 1.01 1.36 538598.2 8478202.8
KYHA0035 0.0 10.0 10.0 1.06 1.58 538799.7 8479200.4
KYHA0054 0.0 11.0 11.0 1.03 2.30 537598.8 8477602.3
KYHA0055 0.0 9.5 9.5 0.80 3.12 537999.6 8477626.7
KYHA0061 0.0 7.0 7.0 0.85 3.47 538790.0 8478777.6
KYHA0066 0.0 15.0 15.0 1.12 1.30 539599.8 8479167.4
KYHA0078 0.0 10.0 10.0 1.12 2.33 541193.6 8481599.6
KYHA0080 0.0 2.0 2.0 1.15 0.01 541998.9 8481598.6
KYHA0105 0.0 14.0 14.0 0.77 0.01 539192.1 8477994.6
KYHA0120 0.0 14.0 14.0 1.24 0.01 539599.5 8479167.7
KYHA0123 0.0 4.0 4.0 1.32 0.01 539993.0 8479995.0
KYHA0126 0.0 2.0 2.0 1.16 0.01 540001.2 8481200.8
KYHA0133 0.0 10.0 10.0 1.53 2.32 537199.6 8477200.6
KYHA0142 3.0 6.0 3.0 1.11 0.20 540798.9 8478800.1
KYHA0157 0.0 10.0 10.0 1.41 2.52 544029.0 8480381.5
KYHA0161 0.0 4.0 4.0 1.48 0.10 543207.2 8482409.4
KYHA0163 0.0 2.0 2.0 1.45 0.01 542455.0 8481633.3
KYHA0164 0.0 9.0 9.0 1.00 0.92 543166.7 8481571.8
KYHA0171 1.0 9.0 8.0 1.47 1.78 542401.2 8480000.8
KYHA0177 0.0 11.0 11.0 1.06 0.74 543243.3 8478790.4
KYHA0178 1.0 3.0 2.0 1.13 0.90 542399.4 8478000.9
KYHA0182 0.0 12.0 12.0 1.30 2.14 540199.3 8479599.0
KYHA0184 0.0 11.0 11.0 0.98 1.67 540998.4 8479605.4
KYHA0202 0.0 5.0 5.0 0.79 0.50 539398.6 8479198.0
KYHA0235 0.0 5.0 5.0 1.11 0.20 541200.5 8478001.0
KYHA0240 0.0 3.0 3.0 1.57 0.30 541600.6 8480399.8
KYHA0246 0.0 9.0 9.0 0.91 1.93 540798.7 8480799.7
KYHA0256 0.0 11.0 11.0 1.19 0.01 537599.0 8477602.1
KYHA0257 0.0 14.0 14.0 0.99 0.01 538598.1 8478202.5
KYHA0258 0.0 3.0 3.0 0.92 0.01 538789.7 8478777.3
KYHA0259 0.0 11.0 11.0 1.31 0.01 539598.7 8479601.1
KYHA0260 0.0 4.0 4.0 1.12 0.01 539600.7 8480400.5
KYHA0261 0.0 4.0 4.0 0.93 0.01 540001.6 8481200.7
KYHA0262 0.0 10.0 10.0 0.91 0.01 541193.5 8481600.0
KYHA0292 0.0 8.0 8.0 1.29 1.71 537600.9 8478798.8
KYHA0308 0.0 4.0 4.0 1.38 0.01 541200.0 8482000.0
KYHA0315 3.0 9.0 6.0 0.89 3.67 542812.2 8479976.7
KYHA0317 0.0 3.0 3.0 1.62 0.01 542800.1 8480800.0
KYHA0328 0.0 4.0 4.0 1.21 0.15 543199.0 8481200.3
KYHA0330 2.0 5.0 3.0 1.02 0.90 542800.1 8481199.8
KYHA0342 2.0 12.0 10.0 0.91 0.75 543599.4 8482799.2
KYHA0343 0.0 5.0 5.0 1.22 0.14 544002.6 8482800.0
KYHA0399 0.0 2.0 2.0 0.71 0.01 542400.0 8477200.8
KYHA0406 4.0 7.0 3.0 1.38 0.01 540415.0 8476800.0
KYHA0425 0.0 5.0 5.0 1.01 0.48 543600.1 8477200.0
KYHA0451 0.0 3.0 3.0 0.78 0.01 544799.9 8476400.0
KYHA0539 0.0 11.0 11.0 0.84 2.13 540200.4 8479198.6
KYHA0540 3.0 8.0 5.0 0.98 0.44 539649.5 8477991.5
KYHA0542 0.0 12.0 12.0 0.88 1.83 542000.3 8476800.9
KYHA0565 0.0 3.0 3.0 1.64 0.40 542400.5 8480001.3
KYHA0568 0.0 12.0 12.0 1.06 2.44 540596.9 8479200.4
KYHA0571 0.0 2.0 2.0 0.70 1.40 540900.6 8476854.4
KYHA0574 0.0 12.0 12.0 0.92 1.98 542400.6 8479601.1
KYHA0578 0.0 2.0 2.0 1.43 0.40 543197.6 8482793.6
KYHA0579 0.0 3.0 3.0 1.09 0.40 542400.8 8476798.8
KYHA0580 0.0 1.0 1.0 0.79 0.40 543998.9 8477999.2
KYHA0581 0.0 3.0 3.0 1.09 0.50 544000.1 8478799.1
KYHA0582 0.0 4.0 4.0 0.75 0.30 545202.6 8476399.9
KYHA0804 0.0 11.0 11.0 1.34 1.31 549198.9 8479601.8
KYHA0811 0.0 12.0 12.0 1.27 1.53 548798.8 8479197.9
KYHA0818 0.0 12.0 12.0 1.26 1.53 548398.8 8478798.4
KYHA0837 0.0 12.0 12.0 1.46 1.68 548799.3 8478401.7
KYHA0838 0.0 12.0 12.0 1.34 1.00 548399.6 8478399.1
KYHA0898 0.0 3.0 3.0 0.95 0.50 539200.6 8480203.0
KYHA0899 0.0 2.0 2.0 1.45 0.50 539606.6 8480200.3
KYHA0899 7.0 12.0 5.0 0.98 6.10 539606.6 8480200.3
KYHA0900 0.0 2.0 2.0 0.79 0.40 540000.9 8480199.9
KYHA0900 10.0 12.0 2.0 0.78 2.90 540000.9 8480199.9
KYHA0901 0.0 13.0 13.0 1.35 2.42 539204.2 8479800.8
KYHA0902 0.0 6.0 6.0 1.31 1.75 539601.7 8479802.0
KYHA0903 0.0 11.0 11.0 1.16 2.20 540001.5 8479800.5
KYHA0904 0.0 12.0 12.0 1.27 2.55 539199.8 8479402.0
KYHA0905 0.0 13.0 13.0 1.23 3.28 539598.7 8479403.0
KYHA0906 0.0 13.0 13.0 1.18 2.95 540400.7 8479803.0
KYHA0907 0.0 10.0 10.0 0.87 0.88 540402.9 8479402.0
KYHA0908 0.0 7.0 7.0 1.03 0.37 540801.9 8479806.6
KYHA0909 0.0 6.0 6.0 1.25 0.33 541202.9 8479802.7
KYHA0910 0.0 2.0 2.0 1.17 0.30 541600.5 8479795.2
KYHA0911 0.0 10.0 10.0 1.08 1.58 541799.6 8479602.8
KYHA0912 0.0 8.0 8.0 1.35 0.86 541200.7 8479401.7
KYHA0913 0.0 12.0 12.0 1.12 2.73 541603.4 8479403.3
KYHA0914 0.0 12.0 12.0 1.31 3.12 540799.5 8479001.5
KYHA0915 0.0 4.0 4.0 1.21 0.35 541203.3 8479000.6
KYHA0916 0.0 12.0 12.0 1.37 1.03 542200.8 8479606.1
KYHA0917 0.0 3.0 3.0 1.41 0.40 542600.8 8479605.0
KYHA0918 0.0 5.0 5.0 1.47 0.20 541998.4 8479799.5
KYHA0920 0.0 11.0 11.0 1.02 1.45 542400.8 8479403.3
KYHA0921 0.0 12.0 12.0 1.01 2.98 538798.7 8479003.5
KYHA0922 0.0 2.0 2.0 1.02 1.20 539197.7 8479002.4
KYHA0923 0.0 6.0 6.0 0.90 2.10 541597.3 8479000.9
KYHA0924 0.0 3.0 3.0 1.39 0.30 540793.1 8479396.3
KYHA0925 0.0 4.0 4.0 1.35 0.25 542400.7 8479803.3
KYHA0926 0.0 12.0 12.0 1.08 1.08 542198.0 8480003.7
KYHA0927 0.0 11.0 11.0 1.46 1.37 542399.7 8480199.7
KYHA0928 0.0 4.0 4.0 1.37 1.00 542003.9 8480199.4
KYHA0929 0.0 8.0 8.0 1.14 1.16 542200.2 8480401.0
KYHA0930 0.0 1.0 1.0 2.10 0.30 541792.0 8480398.1
KYHA0931 0.0 3.0 3.0 1.93 0.20 542597.7 8480801.2
KYHA0932 0.0 2.0 2.0 1.71 0.20 542004.1 8480600.9
KYHA0933 0.0 8.0 8.0 1.44 1.03 542399.2 8480599.3
KYHA0934 0.0 2.0 2.0 1.93 0.40 542189.8 8480801.8
KYHA0935 0.0 6.0 6.0 0.98 1.23 541799.3 8480002.4
KYHA0936 0.0 8.0 8.0 1.24 0.80 542600.6 8480002.5
KYHA0937 0.0 14.0 14.0 1.46 1.39 542800.6 8480200.3
KYHA0938 0.0 12.0 12.0 1.53 1.09 543003.1 8480401.5
KYHA0939 0.0 14.0 14.0 1.13 1.49 543202.0 8480201.7
KYHA0940 0.0 2.0 2.0 1.28 0.30 544003.1 8480202.5
KYHA0941 0.0 7.0 7.0 1.29 0.31 543402.0 8480402.6
KYHA0942 0.0 14.0 14.0 1.18 1.72 543600.4 8480204.5
KYHA0943 0.0 15.0 15.0 1.39 0.82 544200.6 8480401.3
KYHA0944 0.0 12.0 12.0 0.96 0.85 542600.7 8480399.8
KYHA0945 0.0 5.0 5.0 0.95 0.05 543199.4 8479397.3
KYHA0945 11.0 13.0 2.0 0.73 1.90 543199.4 8479397.3
KYHA0946 0.0 14.0 14.0 0.86 1.45 543400.3 8479198.0
KYHA0947 0.0 6.0 6.0 1.19 0.40 543210.0 8478999.1
KYHA0948 0.0 8.0 8.0 1.16 3.00 543599.6 8478999.8
KYHA0949 0.0 4.0 4.0 1.11 0.30 543798.6 8479202.6
KYHA0950 0.0 13.0 13.0 0.93 1.70 543601.1 8479403.6
KYHA0951 0.0 14.0 14.0 1.11 0.99 544398.1 8480601.7
KYHA0952 0.0 12.0 12.0 0.93 0.82 544599.3 8480800.7
KYHA0953 0.0 15.0 15.0 0.95 1.83 544803.0 8480998.8
KYHA0954 0.0 13.0 13.0 1.08 0.95 542798.4 8480599.9
KYHA0955 0.0 11.0 11.0 1.30 1.05 543202.2 8480599.8
KYHA0956 0.0 8.0 8.0 1.10 1.43 543402.7 8480801.7
KYHA0957 0.0 4.0 4.0 1.39 0.06 543004.8 8480805.5
KYHA0958 0.0 7.0 7.0 1.23 0.20 543601.2 8480999.8
KYHA0959 0.0 12.0 12.0 1.01 2.22 543801.4 8480799.3
KYHA0960 0.0 15.0 15.0 1.26 1.48 543998.7 8480601.1
KYHA0961 0.0 14.0 14.0 1.01 2.31 543602.3 8480599.0
KYHA0962 0.0 13.0 13.0 1.20 0.88 543798.4 8480407.6
KYHA0963 0.0 14.0 14.0 1.22 2.24 544001.1 8481006.1
KYHA0964 0.0 10.0 10.0 1.15 2.39 544203.0 8480801.1
KYHA0965 0.0 12.0 12.0 1.14 1.62 544402.9 8481000.7
KYHA0966 0.0 6.0 6.0 1.17 0.37 544602.0 8481201.7
KYHA0967 0.0 8.0 8.0 0.90 0.64 544999.3 8481221.4
KYHA0968 0.0 8.0 8.0 1.31 0.63 544800.3 8481399.7
KYHA0969 0.0 2.0 2.0 1.60 0.30 544409.2 8481401.5
KYHA0970 0.0 2.0 2.0 1.49 0.30 544198.6 8481204.6
KYHA0971 0.0 2.0 2.0 1.20 0.60 543600.6 8478599.5
KYHA0972 0.0 9.0 9.0 1.36 0.99 543401.0 8478801.4
KYHA0973 0.0 5.0 5.0 1.12 0.38 543397.9 8478401.4
KYHA0974 0.0 12.0 12.0 0.95 1.97 543395.8 8477999.4
KYHA0975 0.0 13.0 13.0 0.87 1.68 543601.6 8477802.3
KYHA0976 0.0 12.0 12.0 1.22 1.91 543206.7 8477791.5
KYHA0977 0.0 3.0 3.0 1.16 0.20 542997.7 8477999.4
KYHA0978 0.0 14.0 14.0 1.09 1.94 543597.2 8478200.4
KYHA0979 0.0 5.0 5.0 1.00 0.36 543199.4 8478200.0
KYHA0980 0.0 12.0 12.0 1.16 1.45 543200.9 8478602.1
KYHA0981 0.0 11.0 11.0 0.96 2.03 543005.3 8478395.9
KYHA0983 0.0 15.0 15.0 0.90 3.46 543600.8 8481800.4
KYHA0984 0.0 14.0 14.0 1.17 2.49 539996.8 8479401.4
KYHA0985 0.0 4.0 4.0 1.00 0.50 543402.2 8481602.2
KYHA0987 0.0 15.0 15.0 1.17 1.73 543398.1 8482001.5
KYHA0988 0.0 5.0 5.0 1.15 0.24 543196.4 8482201.4
KYHA0989 0.0 8.0 8.0 1.16 1.63 541802.9 8480803.4
KYHA0990 0.0 14.0 14.0 1.35 1.36 543202.5 8481800.1
KYHA0991 0.0 10.0 10.0 1.02 4.04 543598.5 8482203.6
KYHA0992 0.0 11.0 11.0 1.02 1.26 543402.7 8482405.4
KYHA0993 0.0 2.0 2.0 1.49 0.40 543808.5 8482399.3
KYHA0994 0.0 12.0 12.0 0.94 0.83 543600.8 8482600.2
KYHA0995 0.0 3.0 3.0 1.53 0.20 543997.9 8482597.4
KYHA0996 0.0 4.0 4.0 1.50 0.20 543798.5 8482803.1
KYHA0997 0.0 5.0 5.0 1.09 0.46 544197.2 8483202.8
KYHA0998 0.0 6.0 6.0 0.84 2.50 544599.6 8483200.6
KYHA0999 0.0 2.0 2.0 1.15 0.40 544399.5 8483000.3
KYHA1000 0.0 3.0 3.0 1.32 0.20 544401.8 8483401.1
KYHA1001 0.0 10.0 10.0 0.89 2.87 544202.1 8483597.8
KYHA1002 0.0 13.0 13.0 1.38 1.10 544603.2 8483602.9
KYHA1003 0.0 15.0 15.0 1.12 3.01 545003.8 8483599.5
KYHA1004 0.0 14.0 14.0 1.48 1.51 544801.5 8483801.2
KYHA1005 0.0 9.0 9.0 0.93 1.13 544598.4 8484002.5
KYHA1006 0.0 15.0 15.0 1.07 3.00 545200.2 8483797.5
KYHA1007 0.0 10.0 10.0 1.05 1.11 545001.2 8484006.3
KYHA1008 0.0 7.0 7.0 1.04 0.57 544002.3 8483400.0
KYHA1009 0.0 4.0 4.0 1.41 0.50 544399.9 8483801.6
KYHA1010 0.0 3.0 3.0 1.52 0.60 544801.6 8483401.9
KYHA1011 0.0 2.0 2.0 0.92 0.30 544199.9 8482801.2
KYHA1011 7.0 11.0 4.0 0.89 1.45 544199.9 8482801.2
KYHA1012 0.0 3.0 3.0 1.32 0.20 543993.9 8483002.6
KYHA1013 0.0 5.0 5.0 1.15 0.56 541602.8 8481802.1
KYHA1013 10.0 13.0 3.0 0.77 4.40 541602.8 8481802.1
KYHA1014 0.0 15.0 15.0 0.87 3.17 541800.5 8482000.4
KYHA1015 0.0 10.0 10.0 1.01 1.66 542001.3 8482199.9
KYHA1016 0.0 4.0 4.0 1.38 0.95 543556.7 8483013.2
KYHA1018 0.0 12.0 12.0 1.01 1.93 541999.8 8482597.6
KYHA1019 0.0 14.0 14.0 1.33 2.07 541799.2 8482404.1
KYHA1020 0.0 15.0 15.0 1.18 2.89 541597.1 8482205.0
KYHA1021 0.0 4.0 4.0 1.33 0.35 541400.1 8481999.9
KYHA1021 9.0 11.0 2.0 0.93 4.30 541400.1 8481999.9
KYHA1022 0.0 12.0 12.0 1.28 2.38 541197.4 8481803.0
KYHA1023 0.0 12.0 12.0 1.26 2.60 541396.9 8481601.7
KYHA1024 0.0 12.0 12.0 0.91 2.48 542199.4 8482402.7
KYHA1025 0.0 6.0 6.0 1.08 0.27 541602.0 8482601.8
KYHA1025 13.0 15.0 2.0 0.77 3.60 541602.0 8482601.8
KYHA1026 0.0 2.0 2.0 1.22 0.30 541402.1 8482400.0
KYHA1027 0.0 4.0 4.0 1.02 0.15 541203.2 8482200.4
KYHA1028 0.0 14.0 14.0 1.16 1.92 541003.2 8481601.0
KYHA1029 0.0 12.0 12.0 0.91 2.64 540802.4 8481400.7
KYHA1030 0.0 13.0 13.0 0.91 3.12 541201.0 8481401.4
KYHA1031 0.0 10.0 10.0 1.01 3.30 540998.4 8481209.6
KYHA1032 0.0 2.0 2.0 1.39 0.40 537403.1 8476804.0
KYHA1033 0.0 2.0 2.0 1.33 0.50 536999.1 8476800.4
KYHA1033 10.0 14.0 4.0 1.22 3.90 536999.1 8476800.4
KYHA1034 0.0 16.0 16.0 0.97 3.78 537200.6 8476999.2
KYHA1035 0.0 9.0 9.0 0.97 1.39 537399.2 8477200.3
KYHA1036 0.0 3.0 3.0 1.24 0.70 537000.0 8477204.5
KYHA1037 0.0 14.0 14.0 1.28 1.93 537200.6 8477397.5
KYHA1038 0.0 12.0 12.0 0.97 1.13 537001.5 8477603.4
KYHA1039 0.0 10.0 10.0 1.33 2.65 537405.8 8477595.8
KYHA1040 0.0 3.0 3.0 2.00 1.23 537599.0 8477802.7
KYHA1041 0.0 2.0 2.0 1.85 1.60 537793.2 8478002.7
KYHA1042 0.0 2.0 2.0 1.53 0.60 537799.4 8477602.5
KYHA1043 0.0 6.0 6.0 1.34 2.40 537999.7 8477798.9
KYHA1044 0.0 2.0 2.0 1.31 0.50 537594.1 8477396.0
KYHA1044 9.0 12.0 3.0 0.93 3.40 537594.1 8477396.0
KYHA1045 0.0 2.0 2.0 1.36 0.30 538000.3 8477401.8
KYHA1046 0.0 11.0 11.0 0.90 3.50 537202.0 8477799.0
KYHA1047 0.0 2.0 2.0 1.33 0.70 537400.9 8477999.7
KYHA1048 0.0 8.0 8.0 1.03 4.05 538202.5 8477999.0
KYHA1049 0.0 2.0 2.0 1.76 0.30 540600.2 8479800.5
KYHA1049 8.0 12.0 4.0 0.96 3.90 540600.2 8479800.5
KYHA1050 0.0 10.0 10.0 1.11 0.12 542202.2 8479803.0
KYHA1051 0.0 8.0 8.0 1.48 0.80 542199.9 8480600.2
KYHA1052 0.0 8.0 8.0 1.34 1.88 543400.0 8480600.5
KYHA1053 0.0 14.0 14.0 0.86 0.73 543799.9 8480200.5
KYHA1054 0.0 14.0 14.0 1.28 1.23 539800.1 8479400.6
KYHA1055 0.0 4.0 4.0 1.12 0.40 543800.0 8479000.4
KYHA1056 0.0 11.0 11.0 1.33 2.56 543398.0 8478599.4
KYHA1057 0.0 6.0 6.0 1.48 0.37 541007.2 8481390.6
KYHA1058 0.0 10.0 10.0 1.12 2.06 541395.1 8481801.5
KYHA1059 0.0 2.0 2.0 1.42 0.30 544600.0 8482600.3
KYHA1060 0.0 6.0 6.0 0.98 0.43 544600.0 8483000.2
KYHA1061 0.0 10.0 10.0 1.23 0.44 544599.9 8483800.5
KYHA1062 0.0 12.0 12.0 1.39 1.50 544600.0 8481001.0
KYHA1063 0.0 8.0 8.0 0.92 1.58 537799.8 8477800.3
KYHA1064 0.0 11.0 11.0 1.21 3.23 537000.0 8477400.5
KYHA1065 0.0 14.0 14.0 1.18 2.00 539798.0 8472799.4
KYHA1066 0.0 4.0 4.0 1.21 0.30 538998.0 8472802.8
KYHA1068 0.0 2.0 2.0 0.85 0.30 550438.0 8479180.0
KYHA1079 0.0 4.0 4.0 0.85 0.40 550833.6 8480356.2
KYHA1080 0.0 10.0 10.0 1.01 0.66 550806.6 8479996.4
KYHA1081 0.0 2.0 2.0 1.20 0.10 550799.4 8479599.8
KYHA1114 0.0 3.0 3.0 1.09 0.20 549200.4 8476799.3
KYHA1115 0.0 2.0 2.0 1.13 0.30 548399.8 8478004.8
KYHA1126 0.0 3.0 3.0 1.15 0.20 542400.4 8484801.3
KYHA1136 0.0 4.0 4.0 1.23 0.30 543000.2 8484596.8
KYHA1138 0.0 13.0 13.0 0.90 3.92 542599.4 8484601.1
KYHA1141 0.0 10.0 10.0 1.25 3.37 542599.6 8484205.8
KYHA1143 0.0 5.0 5.0 0.98 0.30 542999.2 8484204.4
KYHA1145 0.0 3.0 3.0 1.15 0.30 542000.1 8483604.7
KYHA1151 0.0 4.0 4.0 0.78 0.40 547202.5 8473202.6
KYHA1173 0.0 12.0 12.0 1.65 1.88 544800.0 8472000.0
KYHA1206 0.0 9.0 9.0 0.97 1.07 542797.5 8465200.6
KYHA1228 0.0 2.0 2.0 0.78 0.20 547202.7 8479201.6
KYHA1231 0.0 4.0 4.0 1.00 0.25 543798.7 8479203.1
KYHA1232 0.0 6.0 6.0 1.33 0.20 540797.8 8478800.2
KYHA1232 13.0 16.0 3.0 0.89 0.20 540797.8 8478800.2
KYHA1233 2.0 10.0 8.0 1.13 0.88 541202.7 8479802.8
KYHA1234 0.0 5.0 5.0 1.38 0.90 542200.7 8480401.6
KYHA1235 0.0 2.0 2.0 1.39 0.20 545616.8 8480378.4
KYHA1236 0.0 2.0 2.0 1.47 0.40 540802.6 8481400.2
KYHA1236 7.0 12.0 5.0 1.05 3.78 540802.6 8481400.2
KYHA1237 0.0 8.0 8.0 1.11 1.50 541802.9 8480803.7
KYHA1238 0.0 4.0 4.0 1.44 0.40 544399.8 8483801.9
KYHA1238 10.0 12.0 2.0 0.79 3.10 544399.8 8483801.9
KYHA1239 0.0 3.0 3.0 0.83 0.20 544800.4 8484401.2
KYHA1240 0.0 8.0 8.0 1.24 0.55 544800.1 8481400.0
KYHA1241 0.0 11.0 11.0 0.94 0.95 546795.7 8484005.9
KYHA1242 0.0 3.0 3.0 0.70 0.20 548400.3 8485999.0
KYHA1243 0.0 7.0 7.0 1.08 0.87 537598.7 8472000.6
KYHA1244 0.0 5.0 5.0 1.15 0.20 540398.6 8473200.9
KYHA1245 0.0 7.0 7.0 1.00 1.44 537599.6 8480402.2
KYHA1246 0.0 12.0 12.0 1.09 0.85 543597.3 8473199.3
KYHA1249 0.0 11.0 11.0 1.08 1.27 546800.3 8476401.0
KYHA1252 0.0 11.0 11.0 1.47 1.78 544404.8 8472006.1
KYHA1253 0.0 5.0 5.0 0.78 0.40 547200.6 8472400.5
KYHA1256 0.0 11.0 11.0 1.14 0.85 542800.1 8470398.8
KYHA1257 0.0 9.0 9.0 1.20 0.94 544796.4 8467603.6
KYHA1258 5.0 7.0 2.0 0.79 1.20 545201.2 8467200.6
KYHA1260 0.0 2.0 2.0 1.22 0.30 542000.3 8468800.3
KYHA1261 0.0 10.0 10.0 1.49 1.00 544000.3 8468409.6
KYHA1263 0.0 5.0 5.0 0.84 0.30 546801.0 8462199.3
KYHA1265 0.0 3.0 3.0 1.33 0.01 546001.0 8465997.1
KYHA1266 0.0 5.0 5.0 0.84 0.96 544799.3 8464400.0
KYHA1328 2.0 4.0 2.0 1.03 0.20 541200.5 8467602.6
KYHA1328 12.0 14.0 2.0 1.78 1.60 541200.5 8467602.6
KYHA1329 0.0 3.0 3.0 0.73 0.20 540406.8 8467602.0
KYHA1330 0.0 2.0 2.0 0.88 0.10 540000.6 8467602.4
KYHA1330 12.0 14.0 2.0 1.40 1.60 540000.6 8467602.4
KYHA1331 11.0 14.0 3.0 1.64 1.80 539598.7 8467598.8
KYHA1332 6.0 9.0 3.0 0.78 0.20 539200.6 8467600.1
KYHA1333 2.0 4.0 2.0 2.03 0.01 545999.8 8469985.6
KYHA1336 0.0 2.0 2.0 1.17 0.01 545997.0 8469601.0
KYHA1343 0.0 2.0 2.0 1.27 0.20 546399.1 8473202.4
KYHA1346 6.0 8.0 2.0 1.10 1.80 545201.8 8473202.2
KYHA1349 0.0 3.0 3.0 1.14 0.50 545997.4 8473998.4
KYHA1350 2.0 14.0 12.0 1.20 1.26 539589.6 8469201.2
KYHA1351 0.0 14.0 14.0 1.00 1.69 540001.6 8469199.1
KYHA1352 2.0 11.0 9.0 0.88 3.42 540802.5 8469200.1
KYHA1357 0.0 3.0 3.0 1.35 0.01 534800.8 8479201.8
KYHA1358 0.0 8.0 8.0 0.98 0.13 536001.7 8480798.3
KYHA1359 0.0 2.0 2.0 0.89 0.20 535995.5 8480399.7
KYHA1360 4.0 7.0 3.0 0.91 0.50 536000.1 8479999.2
KYHA1363 0.0 2.0 2.0 1.09 0.01 539204.0 8466000.4
KYHA1364 0.0 2.0 2.0 1.38 0.01 539601.9 8466000.0
KYHA1365 2.0 12.0 10.0 0.94 0.91 539999.1 8466000.5
KYHA1366 0.0 3.0 3.0 0.84 0.01 540399.4 8465998.7
KYHA1367 0.0 11.0 11.0 0.97 0.82 541195.9 8465996.3
KYHA1368 6.0 8.0 2.0 0.88 3.30 540401.1 8465600.0
KYHA1369 2.0 5.0 3.0 1.07 0.20 540800.8 8465601.2
KYHA1372 0.0 14.0 14.0 1.13 1.19 541198.9 8465207.4
KYHA1373 0.0 2.0 2.0 1.36 0.30 538805.0 8466000.7
KYHA1381 0.0 3.0 3.0 0.76 0.01 535606.4 8465996.1
KYHA1385 0.0 2.0 2.0 0.70 0.01 535600.5 8467602.5
KYHA1390 0.0 2.0 2.0 0.78 0.30 536868.0 8467600.7
KYHA1391 0.0 2.0 2.0 0.75 0.50 536398.6 8467598.3
KYHA1392 0.0 4.0 4.0 0.86 0.20 538391.7 8467604.4
KYHA1393 0.0 2.0 2.0 0.92 0.40 538797.3 8467600.1
KYHA1398 0.0 2.0 2.0 0.75 0.20 534802.6 8469202.5
KYHA1474 0.0 18.0 18.0 1.07 546401.1 8467598.9
KYHA1475 0.0 21.0 21.0 1.00 546300.4 8467504.4
KYHA1476 0.0 17.0 17.0 1.41 545500.1 8465500.1
KYHA1477 0.0 15.0 15.0 1.21 545600.2 8465399.6
KYHA_AC0280 0.0 16.0 16.0 1.15 3.53 544299.8 8468099.8
KYHA_AC0281 0.0 15.0 15.0 1.09 1.39 544499.7 8467900.7
KYHA_AC0282 0.0 4.0 4.0 0.94 0.28 544200.1 8466800.8
KYHA_AC0283 0.0 15.0 15.0 1.19 1.71 543900.9 8467500.1
KYHA_AC0284 0.0 15.0 15.0 1.01 2.43 543900.4 8466301.2
KYHA_AC0285 0.0 16.0 16.0 1.31 1.51 544300.6 8466499.9
KYHA_AC0286 0.0 16.0 16.0 1.34 1.00 545699.3 8465500.4
KYHA_AC0287 0.0 4.0 4.0 1.08 0.25 546099.5 8464901.7
KYHA_AC0288 0.0 15.0 15.0 1.13 0.38 545300.1 8465101.7
KYHA_AC0289 0.0 6.0 6.0 1.64 0.07 545300.3 8465700.7
KYHA_AC0290 0.0 14.0 14.0 1.33 1.06 543699.1 8467700.9
KYHA_AC0291 0.0 16.0 16.0 1.32 0.88 543300.1 8469701.8
KYHA_AC0292 0.0 10.0 10.0 1.30 0.52 543400.7 8470001.4
KYHA_AC0293 0.0 5.0 5.0 1.32 0.12 542899.3 8470101.6
KYHA_AC0293 11.0 14.0 3.0 0.73 0.67 542899.3 8470101.6
KYHA_AC0294 0.0 17.0 17.0 1.41 0.66 543899.7 8471901.2
KYHA_AC0295 0.0 17.0 17.0 1.51 3.63 544701.1 8471501.1
KYHA_AC0296 0.0 7.0 7.0 0.75 1.70 544300.0 8470900.8
KYHA_AC0297 0.0 4.0 4.0 1.65 0.11 544300.3 8472100.4
KYHA_AC0298 0.0 15.0 15.0 1.32 1.15 543301.3 8471701.4
KYHA_AC0299 0.0 16.0 16.0 1.02 1.04 543900.6 8470499.3
KYHA_AC0300 0.0 9.0 9.0 1.09 1.28 543098.7 8471701.1
KYHA_AC0300 15.0 17.0 2.0 0.99 1.16 543098.7 8471701.1
KYHA_AC0301 0.0 13.0 13.0 0.85 3.75 543396.3 8472401.1
KYHA_AC0302 0.0 17.0 17.0 0.96 0.83 543502.3 8472299.4
KYHA_AC0303 0.0 11.0 11.0 1.08 1.16 543801.1 8470000.9
KYHA_AC0304 0.0 14.0 14.0 0.89 1.77 543900.6 8469701.4
KYHA_AC0305 0.0 17.0 17.0 1.35 1.42 544300.9 8468899.7
KYHA_AC0306 0.0 15.0 15.0 1.03 2.01 546099.4 8467300.9
KYHA_AC0307 0.0 12.0 12.0 1.33 3.52 546486.3 8467899.1
KYHA_AC0308 0.0 3.0 3.0 1.80 0.47 543500.3 8468096.3
KYHA_AC0308 9.0 12.0 3.0 0.73 2.57 543500.3 8468096.3
KYHA_AC0309 0.0 17.0 17.0 1.02 4.37 546099.6 8467706.7
KYPT0004 0.0 14.0 14.0 1.14 1.87 539598.1 8479601.2
KYPT0008 0.0 3.0 3.0 0.96 0.50 541602.8 8479597.5
KYPT0016 0.0 6.0 6.0 1.12 1.20 539601.2 8479999.3
KYPT0018 0.0 5.0 5.0 1.13 0.76 541196.1 8478395.4
KYPT0020 0.0 13.0 13.0 0.85 1.36 543597.9 8479601.6
KYPT0022 0.0 13.5 13.5 1.12 0.72 543162.8 8480370.1
KYPT0025 0.0 10.8 10.8 1.43 1.46 543200.6 8478001.2
KYPT0028 0.0 2.0 2.0 1.55 0.40 544000.1 8476798.4
KYPT0029 0.0 10.9 10.9 1.05 1.92 542000.1 8482398.6
KYPT0030 0.0 4.0 4.0 1.17 0.40 544004.1 8484001.7
KYPT0032 0.0 12.8 12.8 0.89 1.88 539198.5 8479600.2
KYPT0033 0.0 4.0 4.0 1.45 0.40 539599.9 8473601.5
KYPT0034 0.0 12.0 12.0 0.87 1.84 542000.4 8473600.1
KYPT0035 0.0 8.7 8.7 0.89 0.25 541600.7 8477201.5
KYPT0065 0.0 6.0 6.0 1.01 0.23 541399.2 8478999.3
KYPT0075 0.0 10.0 10.0 1.37 2.02 542598.6 8480199.4
KYPT0098 0.0 4.0 4.0 0.73 1.10 543799.1 8481399.3
KYPT0119 0.0 10.0 10.0 0.84 0.51 543004.2 8482202.6
KYPT0139 0.0 4.0 4.0 0.97 0.60 543800.8 8478602.5
KYPT0188 0.0 13.0 13.0 0.93 3.01 539800.6 8474400.9
KYPT0211 0.0 2.0 2.0 1.26 0.60 537000.4 8477799.3
KYPT0256 0.0 12.0 12.0 1.00 0.82 547792.7 8477400.1
KYPT0277 0.0 2.0 2.0 1.15 0.20 546195.9 8475402.9
KYPT0326 0.0 2.0 2.0 1.46 0.20 543000.9 8469802.7
KYPT0330 0.0 4.0 4.0 1.52 0.29 548999.7 8479394.3
KYPT0357 0.0 2.0 2.0 1.15 0.15 546601.5 8468200.3
KYPT0378 0.0 7.0 7.0 1.03 1.65 545798.9 8467800.5
KYPT0404 0.0 3.0 3.0 1.09 0.07 543798.7 8484602.0
KYPT0431 0.0 2.0 2.0 1.48 0.30 544999.0 8465798.8
KYPT0451 0.0 9.0 9.0 1.01 0.74 545805.0 8483800.0
KYSA0001 0.0 15.0 15.0 1.14 1.97 544264.3 8466436.3
KYSA0002 0.0 18.8 18.8 1.23 1.67 545203.9 8465392.4
KYSA0003 0.0 17.0 17.0 1.10 1.58 545188.8 8464977.3
KYSA0004 0.0 17.0 17.0 1.32 3.63 545342.9 8465610.0
KYSA0005 0.0 19.6 19.6 1.22 1.71 545938.7 8465730.3
KYSA0007 0.0 12.0 12.0 1.11 1.30 544158.0 8466997.0
KYSA0013 0.0 3.0 3.0 1.52 0.53 545245.2 8468438.9
KYSA0014 0.0 12.0 12.0 1.20 1.18 545189.9 8468917.2
KYSA0015 0.0 10.0 10.0 1.41 1.02 544251.5 8469119.6
KYSA0016 0.0 16.0 16.0 1.07 1.85 544258.1 8468779.7
KYSA0017 0.0 2.0 2.0 1.68 0.45 543512.5 8468319.0
KYSA0018 0.0 2.0 2.0 1.50 0.60 543497.5 8467582.8
KYSA0018 7.0 12.0 5.0 0.75 2.66 543497.5 8467582.8
KYSA0019 0.0 14.4 14.4 0.88 2.58 543512.3 8467918.9
KYSA0020 0.0 17.9 17.9 0.98 1.59 543911.7 8467925.8
KYSA0021 0.0 17.6 17.6 1.10 1.61 543925.3 8468325.2
KYSA0022 0.0 16.0 16.0 1.42 1.67 544219.6 8468361.0
KYSA0023 0.0 18.0 18.0 1.06 2.03 544258.4 8467926.1
KYSA0024 0.0 12.0 12.0 1.09 1.38 543803.9 8469770.9
KYSA0025 0.0 10.0 10.0 1.15 1.42 543691.8 8470265.5
KYSA0026 0.0 7.0 7.0 1.11 1.83 544051.7 8470849.2
KYSA0026 13.0 15.0 2.0 0.73 2.90 544051.7 8470849.2
KYSA0027 0.0 14.0 14.0 1.00 5.11 543988.9 8470403.1
KYSA0028 0.0 4.0 4.0 1.07 0.28 547250.0 8467214.7
KYSA0029 0.0 18.0 18.0 1.18 4.92 546587.3 8467493.3
KYSA0030 0.0 16.0 16.0 1.14 0.86 546988.0 8467493.0
KYSA0031 0.0 14.0 14.0 0.98 4.31 546184.9 8467595.2
KYSA0032 0.0 9.0 9.0 1.01 1.98 546800.3 8467899.7
KYSA0033 0.0 8.0 8.0 1.19 3.34 546398.7 8467906.0
KYSA0033 14.0 18.0 4.0 0.87 5.63 546398.7 8467906.0
KYSA0035 0.0 6.0 6.0 1.17 0.62 547070.8 8468620.3
KYSA0036 0.0 4.0 4.0 1.07 0.13 546604.3 8468573.1
KYSA0037 0.0 14.0 14.0 1.09 2.22 546135.8 8468668.8
KYSA0038 0.0 14.0 14.0 1.07 1.80 543199.6 8469505.2
KYSA0039 0.0 14.0 14.0 1.24 1.91 543200.2 8469904.8
KYSA0040 0.0 15.0 15.0 1.22 2.01 543202.6 8470284.5
KYSA0043 0.0 3.0 3.0 1.13 0.83 547150.9 8470004.0
KYSA0046 0.0 2.0 2.0 1.40 0.25 547228.8 8472516.5
KYSA0047 0.0 10.0 10.0 1.15 1.24 543789.1 8473001.4
KYSA0048 0.0 4.0 4.0 1.53 0.03 544005.3 8471901.3
KYSA0049 0.0 2.0 2.0 1.70 0.35 543600.0 8472300.5
KYSA0049 8.0 14.0 6.0 0.84 3.70 543600.0 8472300.5
KYSA0050 0.0 14.0 14.0 1.07 1.68 543600.1 8471500.0
KYSA0051 0.0 20.0 20.0 1.22 1.81 543601.3 8471901.0
KYSA0052 0.0 12.0 12.0 1.09 1.41 543221.1 8471103.3
KYSA0053 0.0 9.0 9.0 1.05 2.36 543208.8 8472303.0
KYSA0054 0.0 9.6 9.6 1.20 1.40 543199.3 8471899.4
KYSA0055 0.0 17.0 17.0 1.10 2.54 544404.7 8471902.8
KYSA0056 0.0 14.0 14.0 1.11 2.50 540159.6 8474394.7
KYSA0057 0.0 11.8 11.8 0.99 3.15 539600.5 8472966.0
KYSA0058 0.0 3.0 3.0 1.31 0.23 539189.4 8472834.8
KYSA0059 0.0 14.0 14.0 1.00 1.92 539795.5 8472529.4
KYSA0060 0.0 12.0 12.0 1.04 2.44 539004.3 8472150.0
KYSA0061 0.0 12.0 12.0 1.05 2.40 539737.1 8472024.5
KYSA0062 0.0 19.0 19.0 1.35 1.60 545200.4 8465395.1
KYSA0063 0.0 20.0 20.0 1.04 1.09 545635.0 8465502.8
KYSA0064 0.0 19.9 19.9 1.32 2.97 545341.4 8465615.2
KYSA0065 0.0 19.8 19.8 1.20 1.55 545937.6 8465731.6
KYSA0066 0.0 16.6 16.6 1.07 2.06 544259.5 8467923.9
KYSA0067 0.0 17.2 17.2 1.30 1.78 544220.6 8468364.7
KYSA0088 0.0 8.0 8.0 1.14 544299.6 8471701.1
KYSA0090 0.0 8.0 8.0 1.15 544700.4 8472098.5
KYSA0092 0.0 8.0 8.0 1.21 543299.5 8472102.2
KYSA0094 0.0 8.0 8.0 1.37 543499.1 8471502.7
KYSA0096 0.0 8.0 8.0 1.18 543200.6 8470201.0
KYSA0098 0.0 8.0 8.0 1.20 543100.6 8469901.5
KYSA0100 0.0 7.0 7.0 1.24 543399.9 8469601.3
KYSA0102 0.0 8.0 8.0 1.13 543900.3 8468102.1
KYSA0104 0.0 8.0 8.0 1.17 544499.4 8468698.3
KYSA0106 0.0 4.0 4.0 1.41 0.60 543500.9 8472098.5
KYSA0107 0.0 4.0 4.0 1.52 1.20 543301.6 8472300.2
KYSA0108 0.0 4.0 4.0 1.51 0.85 543099.8 8472300.1
KYSA0109 0.0 2.0 2.0 1.38 0.45 542899.4 8472298.9
KYSA0110 0.0 2.0 2.0 1.27 1.75 543099.6 8472100.4
KYSA0111 0.0 5.0 5.0 1.30 1.80 542898.3 8472099.8
KYSA0112 0.0 2.0 2.0 1.48 0.65 542999.2 8472000.7
KYSA0113 0.0 3.0 3.0 1.47 0.50 543098.7 8471899.9
KYSA0114 0.0 4.0 4.0 1.20 1.00 543300.4 8471901.5
KYSA0115 0.0 4.0 4.0 1.50 0.48 543699.7 8472100.5
KYSA0116 0.0 3.0 3.0 1.63 0.27 544100.5 8472099.8
KYSA0117 0.0 4.0 4.0 1.08 0.45 544498.6 8472098.4
KYSA0118 0.0 2.0 2.0 1.52 0.20 544500.6 8472299.9
KYSA0119 0.0 2.0 2.0 1.25 0.25 544600.4 8472400.6
KYSA0120 0.0 2.0 2.0 1.67 0.30 544699.2 8472299.1
KYSA0122 0.0 2.0 2.0 0.87 0.45 544900.0 8472499.2
KYSA0123 0.0 2.0 2.0 0.89 0.45 544999.6 8472399.9
KYSA0124 0.0 2.0 2.0 1.12 1.15 544900.2 8472300.9
KYSA0125 0.0 4.0 4.0 1.41 0.30 544800.5 8472200.7
KYSA0126 0.0 4.0 4.0 1.09 0.85 544900.1 8472098.7
KYSA0128 0.0 3.0 3.0 1.41 0.23 544500.5 8467699.9
KYSA0129 0.0 2.0 2.0 1.52 0.11 544600.6 8467600.5
KYSA0130 0.0 4.0 4.0 1.12 0.13 544499.4 8467500.1
KYSA0131 0.0 4.0 4.0 1.50 0.55 544198.8 8467600.0
KYSA0132 0.0 6.0 6.0 1.33 0.83 544298.5 8467699.8
KYSA0133 0.0 4.0 4.0 1.55 0.28 544098.7 8467900.0
KYSA0134 0.0 4.0 4.0 1.72 0.48 544293.5 8468300.3
KYSA0135 0.0 6.0 6.0 1.44 0.45 544100.8 8468300.6
KYSA0136 0.0 4.0 4.0 1.45 0.68 544102.5 8468100.1
KYSA0137 0.0 3.0 3.0 1.57 0.33 544499.5 8468100.7
KYSA0138 0.0 6.0 6.0 1.10 0.65 544500.4 8468299.5
KYSA0139 0.0 6.0 6.0 1.75 0.50 544698.4 8468500.6
KYSA0140 0.0 5.0 5.0 1.58 0.34 544499.3 8468501.0
KYSA0141 0.0 6.0 6.0 0.90 0.52 544700.4 8468700.0
KYSA0142 0.0 6.0 6.0 1.07 1.18 544499.5 8468900.0
KYSA0143 0.0 6.0 6.0 0.74 0.78 544699.4 8468901.1
KYSA0144 0.0 2.0 2.0 0.77 0.25 544797.7 8468999.7
KYSA0145 0.0 4.0 4.0 1.90 0.40 544299.7 8468701.0
KYSA0146 0.0 4.0 4.0 1.85 0.25 544299.3 8468499.0
KYSA0147 0.0 4.0 4.0 1.75 0.23 544099.1 8468501.0
KYSA0148 0.0 2.0 2.0 2.09 0.45 543698.8 8468100.0
KYSA0149 0.0 6.0 6.0 1.20 0.35 543699.4 8467897.0
KYSA0150 0.0 4.0 4.0 1.68 0.33 543898.4 8467700.0
KYSA0151 0.0 3.0 3.0 1.40 0.40 544098.7 8467699.9
KYSA0152 0.0 4.0 4.0 1.55 1.15 543401.3 8467799.6
KYSA0153 0.0 2.0 2.0 1.30 0.35 543499.2 8467701.7
KYSA0154 0.0 4.0 4.0 1.45 0.65 543500.1 8467501.3
KYSA0155 0.0 2.0 2.0 0.88 0.06 543601.6 8467401.9
KYSA0156 0.0 3.0 3.0 1.70 0.04 543699.8 8467499.7
KYSA0157 0.0 2.0 2.0 1.62 0.01 543699.6 8467302.0
KYSA0158 0.0 4.0 4.0 1.14 0.03 543800.1 8467202.3
KYSA0159 0.0 4.0 4.0 1.19 0.13 543900.5 8467305.3
KYSA0160 0.0 5.0 5.0 1.13 0.09 543900.3 8467100.2
KYSA0161 0.0 3.0 3.0 1.19 0.04 543699.9 8467100.1
KYSA0162 0.0 6.0 6.0 1.16 1.05 543699.9 8466699.9
KYSA0163 0.0 6.0 6.0 1.15 0.67 543600.1 8466600.0
KYSA0164 0.0 3.0 3.0 1.35 0.17 543700.1 8466900.1
KYSA0165 0.0 4.0 4.0 1.32 0.13 543800.3 8466800.3
KYSA0166 0.0 4.0 4.0 1.26 0.33 543899.3 8466900.4
KYSA0167 0.0 4.0 4.0 1.58 0.20 543899.5 8466700.0
KYSA0168 0.0 4.0 4.0 1.20 0.01 544099.5 8466700.0
KYSA0169 0.0 6.0 6.0 1.31 0.32 544100.8 8466899.0
KYSA0170 0.0 5.0 5.0 1.12 0.09 544000.6 8467000.0
KYSA0171 0.0 5.0 5.0 1.30 0.20 544099.8 8467101.0
KYSA0172 0.0 6.0 6.0 1.03 0.47 544198.5 8467204.8
KYSA0173 0.0 3.0 3.0 1.40 0.23 544299.7 8467100.6
KYSA0174 0.0 4.0 4.0 1.42 0.28 544500.1 8467099.7
KYSA0175 0.0 4.0 4.0 1.17 0.18 544599.3 8467200.3
KYSA0176 0.0 2.0 2.0 0.97 0.15 544699.8 8467294.1
KYSA0177 0.0 3.0 3.0 1.39 0.30 544499.7 8467300.1
KYSA0178 0.0 4.0 4.0 0.96 0.58 544399.7 8467400.0
KYSA0179 0.0 4.0 4.0 1.21 0.75 544299.6 8467500.1
KYSA0180 0.0 4.0 4.0 1.31 0.50 544099.6 8467500.0
KYSA0181 0.0 2.0 2.0 1.54 0.25 544299.6 8467299.9
KYSA0182 0.0 2.0 2.0 1.34 0.25 544099.0 8467300.1
NSHA0004 0.0 11.5 11.5 1.24 1.53 543599.9 8471600.1
NSHA0005 0.0 12.0 12.0 1.21 1.43 543999.5 8470800.0
NSHA0009 0.0 9.0 9.0 1.38 1.43 543599.9 8468399.9
NSHA0010 0.0 5.0 5.0 1.88 0.30 544399.9 8468400.1
NSHA0012 0.0 7.0 7.0 0.97 4.27 546000.0 8467599.9
NSHA0036 0.0 3.0 3.0 1.34 0.30 544005.2 8471600.0
NSHA0056 0.0 10.0 10.0 1.52 1.10 544400.0 8469200.0
NSHA0073 0.0 8.0 8.0 1.04 0.49 543599.3 8467597.7
NSHA0224 0.0 10.0 10.0 1.26 1.02 545600.1 8465200.5
NSHA0225 0.0 12.0 12.0 1.31 1.14 545200.0 8465200.0
NSHA0261 0.0 12.0 12.0 1.23 1.58 543999.9 8471998.4
NSHA0262 0.0 13.0 13.0 1.34 1.54 543600.0 8471997.9
NSHA0263 0.0 9.0 9.0 1.35 0.90 543198.7 8471997.2
NSHA0289 0.0 10.0 10.0 1.19 2.14 544400.0 8471600.0
NSHA0290 0.0 8.0 8.0 1.21 1.63 544001.2 8471199.3
NSHA0297 0.0 12.0 12.0 1.10 3.82 544000.0 8470400.0
NSHA0311 0.0 12.0 12.0 1.41 2.14 544400.1 8468800.4
NSHA0316 0.0 12.0 12.0 1.07 4.36 546400.2 8468000.2
NSHA0344 0.0 12.0 12.0 1.30 1.99 544399.3 8467997.9
NSHA0345 0.0 10.0 10.0 1.49 1.47 544001.9 8468004.4
NSHA0350 2.0 11.0 9.0 1.09 2.40 543601.4 8468000.9
NSHA0359 0.0 6.0 6.0 1.09 1.75 545997.2 8466401.0
NSHA0360 0.0 9.0 9.0 1.09 1.13 546001.2 8465997.6
NSHA0363 0.0 13.0 13.0 1.52 1.18 545199.9 8465600.4
NSHA0364 0.0 12.0 12.0 1.25 1.03 545600.2 8465601.0
NSHA0398 0.0 9.0 9.0 1.04 0.93 546597.0 8475000.4
NSHA0399 0.0 11.0 11.0 1.28 0.85 547005.0 8475798.3
NSHA0400 0.0 11.0 11.0 1.45 1.29 543799.5 8471801.0
NSHA0401 0.0 4.0 4.0 1.56 0.30 544599.0 8472201.3
NSHA0402 0.0 12.0 12.0 1.46 1.28 544201.9 8469000.3
NSHA0403 0.0 10.0 10.0 1.45 0.62 544200.7 8468600.3
NSHA0404 0.0 5.0 5.0 1.40 0.13 544600.1 8467800.6
NSHA0405 0.0 13.0 13.0 1.47 1.42 545400.2 8465400.2
NSPT0022 0.0 6.0 6.0 0.97 0.87 544594.3 8468998.7
NSPT0041 0.0 8.0 8.0 1.02 1.63 546598.4 8475797.3
OBSAC0013 4.0 7.0 3.0 0.75 2.90 541792.7 8467522.0
OBSAC0013 20.0 23.0 3.0 0.71 4.20 541792.7 8467522.0
OBSAC-02 0.0 16.5 16.5 1.09 1.42 547004.2 8474993.8
OBSAC-07 0.0 22.0 22.0 1.05 3.32 540197.1 8479600.4
OBSAC-08 0.0 17.5 17.5 0.90 3.72 539540.8 8472407.3
OBSDD_01A 0.0 2.5 2.5 2.17 0.26 548595.3 8478602.3
OBSDD_01A 2.6 3.9 1.4 0.74 0.50 548595.3 8478602.3
OBSDD_01A 3.9 6.5 2.6 0.97 1.51 548595.3 8478602.3
OBSDD_01A 7.6 8.6 1.0 0.99 1.60 548595.3 8478602.3
OBSDD_01A 11.1 11.6 0.5 1.18 548595.3 8478602.3
OBSDD_01B 0.0 6.4 6.4 1.44 0.69 548592.3 8478590.8
OBSDD_01B 6.6 7.0 0.4 0.82 548592.3 8478590.8
OBSDD_01B 7.7 8.5 0.8 0.77 1.30 548592.3 8478590.8
OBSDD_01B 11.2 11.5 0.4 0.83 548592.3 8478590.8
OBSDD_01B 12.5 13.0 0.6 0.99 548592.3 8478590.8
OBSDD_01B 14.2 14.5 0.4 0.71 548592.3 8478590.8
OBSDD_01B 15.4 16.0 0.6 0.78 1.50 548592.3 8478590.8
OBSDD_01B 16.9 17.5 0.7 0.82 1.10 548592.3 8478590.8
OBSDD_01B 18.1 19.0 0.9 0.81 1.30 548592.3 8478590.8
OBSDD_01B 21.0 21.6 0.6 0.77 1.60 548592.3 8478590.8
OBSDD_03 0.0 8.7 8.7 1.35 3.44 546603.8 8467803.5
OBSDD_03 9.7 10.0 0.3 0.81 546603.8 8467803.5
OBSDD_03 11.0 11.4 0.4 0.75 546603.8 8467803.5
OBSDD_03 13.1 14.5 1.4 0.82 5.00 546603.8 8467803.5
OBSDD_04 0.0 7.3 7.3 1.77 0.71 545195.7 8465397.9
OBSDD_04 7.3 8.5 1.2 1.41 1.90 545195.7 8465397.9
OBSDD_04 8.7 10.0 1.3 1.49 2.10 545195.7 8465397.9
OBSDD_04 10.3 11.5 1.2 1.44 2.20 545195.7 8465397.9
OBSDD_04 12.3 13.0 0.7 1.16 545195.7 8465397.9
OBSDD_04 13.6 14.5 0.9 1.12 2.00 545195.7 8465397.9
OBSDD_04 15.1 16.0 0.8 1.30 2.30 545195.7 8465397.9
OBSDD_04 16.3 17.5 1.2 1.04 2.30 545195.7 8465397.9
OBSDD_04 18.5 18.8 0.3 1.14 545195.7 8465397.9
OBSDD_05 0.0 5.6 5.6 1.28 0.64 543999.2 8468195.2
OBSDD_05 6.5 7.1 0.6 0.88 543999.2 8468195.2
OBSDD_05 9.5 10.1 0.6 0.74 543999.2 8468195.2
OBSDD_06 0.0 10.2 10.2 1.46 1.43 543803.7 8471799.1
OBSDD_06 10.9 11.6 0.7 0.85 1.80 543803.7 8471799.1
OBSDD_06 13.4 14.6 1.2 0.82 2.20 543803.7 8471799.1
OBSDD_06 14.7 16.1 1.4 1.12 1.90 543803.7 8471799.1
OBSDD_06 16.4 17.1 0.7 0.79 1.70 543803.7 8471799.1
RGHA0120 2.0 5.0 3.0 0.81 0.50 536801.9 8473595.6
RGHA0120 12.0 14.0 2.0 2.10 1.60 536801.9 8473595.6
RGHA0123 0.0 2.0 2.0 1.14 0.01 536794.7 8473999.8
RGHA0124 2.0 10.0 8.0 0.96 0.27 536393.0 8474035.6
RGHA0125 0.0 2.0 2.0 0.97 0.20 537200.1 8474604.2
RGHA0125 7.0 10.0 3.0 0.72 3.60 537200.1 8474604.2
RGHA0126 2.0 12.0 10.0 1.15 2.19 540823.3 8472401.0
RGHA0127 0.0 11.0 11.0 0.91 1.18 541208.8 8472399.6
RGHA0129 0.0 2.0 2.0 0.84 0.01 542006.3 8472399.2
RGHA0133 6.0 12.0 6.0 1.14 2.03 539295.4 8467221.0
RGHA0139 0.0 2.0 2.0 1.40 0.20 545998.6 8485601.9
RGHA0139 9.0 12.0 3.0 1.34 0.50 545998.6 8485601.9
RGHA0140 0.0 3.0 3.0 1.22 0.01 545226.4 8485603.5
RGHA0141 0.0 2.0 2.0 0.89 0.01 545210.6 8485222.6
RGHA0141 8.0 10.0 2.0 0.76 0.01 545210.6 8485222.6
RGHA0150 8.0 12.0 4.0 1.43 2.35 550011.5 8481598.1
RGHA0151 0.0 12.0 12.0 0.79 0.68 550403.5 8481617.3
RGHA0154 2.0 4.0 2.0 1.16 0.30 552000.3 8481594.5
RGHA0156 0.0 3.0 3.0 1.06 0.01 553199.8 8481610.9
RGHA0157 9.0 12.0 3.0 1.47 1.70 552391.8 8480799.1
RGHA0159 3.0 5.0 2.0 1.03 0.01 551554.0 8480823.2
RGHA0160 0.0 2.0 2.0 0.86 0.01 551618.8 8480400.2
RGHA0162 0.0 3.0 3.0 1.71 0.01 551193.5 8480827.7
RGHA0164 0.0 1.0 1.0 0.74 0.01 550411.4 8480821.1
RGHA0165 2.0 4.0 2.0 0.84 0.01 550003.7 8480799.3
RGHA0165 9.0 11.0 2.0 1.67 1.50 550003.7 8480799.3
RGHA0166 0.0 3.0 3.0 1.08 0.01 554002.0 8484403.3
RGHA0167 4.0 12.0 8.0 0.79 0.58 553218.1 8484382.0
RGHA0170 4.0 9.0 5.0 1.51 2.50 551198.8 8481601.5
RGHA0175 2.0 12.0 10.0 0.93 0.60 538500.2 8468401.6
RGHA0176 0.0 5.0 5.0 1.60 0.76 538870.4 8468423.7
RGHA0194 0.0 11.0 11.0 0.93 2.98 542403.5 8461207.3
RGHA0195 0.0 2.0 2.0 1.07 0.30 542810.0 8461212.6
RGHA0276 0.0 12.0 12.0 1.53 1.78 567402.4 8505202.1
RGHA0277 0.0 2.0 2.0 0.81 0.30 567802.3 8505207.9
RGHA0278 0.0 2.0 2.0 1.27 0.10 566998.6 8504403.6
RGHA0279 0.0 3.0 3.0 0.83 0.10 567402.4 8504404.1
RGHA0280 0.0 5.0 5.0 0.90 0.34 567800.5 8504439.1
RGHA0282 0.0 2.0 2.0 0.99 0.20 563400.0 8503200.0
RGHA0283 0.0 3.0 3.0 0.81 0.01 564200.4 8503199.6
RGHA0284 0.0 2.0 2.0 0.97 0.20 564998.6 8503200.8
RGHA0285 0.0 3.0 3.0 2.07 0.20 568603.3 8503997.3
RGHA0286 0.0 3.0 3.0 1.07 0.50 569004.0 8504008.3
RGHA0287 0.0 8.0 8.0 1.19 0.80 569394.9 8504004.3
RGHA0288 0.0 2.0 2.0 0.70 0.30 569796.1 8504002.4
RGHA0289 0.0 2.0 2.0 2.84 0.20 568597.9 8503601.0
RGHA0290 0.0 6.0 6.0 1.35 0.95 567400.5 8503201.0
RGHA0291 0.0 5.0 5.0 1.09 0.44 567802.6 8503206.1
RGHA0292 0.0 2.0 2.0 1.23 0.10 568203.9 8503208.1
RGHA0293 0.0 4.0 4.0 1.43 0.25 568595.9 8503213.7
RGHA0294 0.0 11.0 11.0 1.26 0.84 568999.9 8503186.6
RGHA0295 0.0 7.0 7.0 0.76 1.80 569400.0 8503199.9
RGHA0296 0.0 4.0 4.0 1.19 0.85 569800.4 8503200.2
RGHA0298 0.0 2.0 2.0 0.89 1.10 570201.3 8502398.4
RGHA0300 0.0 2.0 2.0 1.35 0.70 569399.8 8502364.4
RGHA0301 0.0 3.0 3.0 1.09 0.01 568992.2 8502446.6
RGHA0302 0.0 3.0 3.0 0.87 0.01 567013.1 8502804.2
RGHA0303 0.0 2.0 2.0 0.76 0.30 567399.9 8502800.2
RGHA0304 0.0 12.0 12.0 0.87 0.85 567801.5 8502804.4
RGHA0305 0.0 12.0 12.0 0.86 1.64 568207.1 8502800.6
RGHA0306 0.0 8.0 8.0 1.02 1.58 568603.4 8502806.1
RGHA0307 0.0 2.0 2.0 0.76 0.01 569008.1 8502796.0
RGHA0308 0.0 3.0 3.0 0.89 0.01 568603.3 8502399.5
RGHA0309 0.0 3.0 3.0 0.85 0.01 567004.0 8502001.8
RGHA0310 0.0 3.0 3.0 0.97 0.01 567024.0 8502408.7
RGHA0312 0.0 5.0 5.0 0.90 1.80 567796.8 8502007.9
RGHA0313 0.0 12.0 12.0 0.96 0.79 568205.4 8502012.4
RGHA0314 0.0 2.0 2.0 0.77 0.01 568600.5 8502003.3
RGHA0316 0.0 12.0 12.0 0.83 0.97 565800.5 8506402.0
RGHA0318 0.0 2.0 2.0 0.82 0.01 564202.0 8506399.1
RGHA0326 0.0 3.0 3.0 0.90 0.01 563800.4 8510408.9
RGHA0328 0.0 2.0 2.0 1.01 0.40 562200.4 8510401.3
RGHA0329 0.0 2.0 2.0 0.94 0.01 566201.0 8513408.1
RGHA0333 0.0 3.0 3.0 1.14 0.01 563007.6 8513414.6
RGHA0333 8.0 12.0 4.0 0.78 3.20 563007.6 8513414.6
RGHA0334 0.0 3.0 3.0 0.73 0.40 562208.5 8513406.9
RGHA0334 9.0 12.0 3.0 0.75 3.00 562208.5 8513406.9
RGHA0335 0.0 10.0 10.0 0.95 1.91 561805.4 8516206.3
RGHA0336 0.0 5.0 5.0 0.91 0.46 561411.1 8515411.7
RGHA0337 0.0 3.0 3.0 0.81 0.50 561795.2 8515416.0
RGHA0338 0.0 2.0 2.0 0.95 0.01 562197.9 8515407.0
RGHA0339 0.0 2.0 2.0 1.24 0.01 560993.1 8517399.1
RGHA0340 0.0 4.0 4.0 1.30 0.01 561400.4 8517405.5
RGHA0341 0.0 4.0 4.0 0.98 0.01 561800.6 8517401.4
RGHA0342 0.0 2.0 2.0 0.89 0.01 562228.9 8517407.9
RGHA0343 0.0 3.0 3.0 1.19 0.01 561800.7 8516609.9
RGHA0344 0.0 5.0 5.0 1.37 0.18 562196.1 8516611.3
RGHA0345 0.0 12.0 12.0 0.89 1.96 562203.9 8516208.7
RGHA0346 0.0 9.0 9.0 0.79 0.01 565003.0 8499605.2
RGHA0347 0.0 2.0 2.0 0.78 0.01 564604.8 8499606.4
RGHA0348 0.0 4.0 4.0 0.91 0.11 565402.1 8499611.0
RGHA0348 9.0 12.0 3.0 1.67 0.20 565402.1 8499611.0
RGHA0352 0.0 10.0 10.0 0.80 1.43 559205.0 8492806.5
RGHA0353 0.0 12.0 12.0 0.91 1.63 560005.9 8492807.8
RGHA0354 0.0 4.0 4.0 0.89 0.01 560794.6 8492809.9
RGHA0355 0.0 3.0 3.0 1.82 0.01 561599.7 8492800.6
RGHA0356 0.0 3.0 3.0 0.94 0.01 562400.0 8492799.9
RGHA0357 0.0 2.0 2.0 1.10 0.30 563200.2 8492803.5
RGHA0360 0.0 2.0 2.0 1.06 0.01 546400.8 8487602.0
RGHA0361 0.0 3.0 3.0 0.99 0.01 546803.2 8487606.8
RGHA0363 0.0 6.0 6.0 1.10 0.03 546800.1 8487204.6
RGHA0366 0.0 2.0 2.0 0.83 0.01 547601.1 8488800.3
RGHA0367 0.0 1.0 1.0 0.80 0.01 547602.8 8488447.1
RGHA0368 0.0 2.0 2.0 0.92 0.01 547601.5 8488003.4
RGHA0369 0.0 12.0 12.0 1.07 1.52 547600.5 8487603.2
RGHA0370 0.0 2.0 2.0 1.49 0.01 547596.6 8487199.8
RGHA0370 10.0 12.0 2.0 1.23 0.50 547596.6 8487199.8
RGHA0375 0.0 2.0 2.0 0.71 1.00 550298.1 8485971.8
RGHA0376 0.0 8.0 8.0 1.06 1.29 550002.2 8485999.0
RGHA0377 0.0 9.0 9.0 0.87 0.01 549601.5 8485998.0
RGHA0411 0.0 2.0 2.0 1.05 0.01 552795.5 8489600.2
RGHA0413 6.0 9.0 3.0 0.82 0.30 552000.0 8489599.9
RGHA0415 0.0 10.0 10.0 0.78 0.78 551200.0 8489600.0
RGHA0417 0.0 2.0 2.0 0.75 0.10 550400.9 8489598.5
RGHA0421 0.0 6.0 6.0 0.97 0.35 551607.6 8489211.1
RGHA0525 0.0 2.0 2.0 0.95 0.01 542112.2 8460922.2
RGHA0526 0.0 2.0 2.0 1.14 0.30 542512.9 8460922.0
RGHA0530 0.0 2.0 2.0 1.12 0.40 542294.9 8461636.4
RGHA0536 2.0 11.0 9.0 0.74 3.36 534400.4 8469198.2
RGHA0542 0.0 3.0 3.0 0.99 0.20 550018.3 8482002.0
RGHA0542 9.0 12.0 3.0 0.87 0.80 550018.3 8482002.0
RGHA0543 0.0 3.0 3.0 1.05 0.01 550416.2 8482008.0
RGHA0553 0.0 2.0 2.0 0.94 0.60 551607.6 8481200.0
RGHA0554 6.0 10.0 4.0 0.80 2.90 551208.0 8481200.7
RGHA0557 0.0 11.0 11.0 0.82 1.01 550008.0 8481200.0
RGHA0629 0.0 2.0 2.0 0.86 0.01 539601.9 8467999.8
RGHA0631 0.0 6.0 6.0 0.89 0.01 539600.2 8468799.8
RGHA0632 0.0 12.0 12.0 0.85 1.12 539996.0 8468801.0
RGHA0638 0.0 12.0 12.0 0.93 2.33 545999.7 8461800.0
RGHA0664 3.0 7.0 4.0 0.73 2.20 538800.3 8466399.8
RRHA0002 0.0 7.0 7.0 0.78 538904.1 8462692.5
RRHA0003 0.0 5.0 5.0 1.08 0.01 538717.4 8462609.0
RRHA0004 0.0 6.0 6.0 0.70 538554.7 8462498.0
RRHA0006 0.0 4.0 4.0 0.89 538253.4 8462197.5
RRHA0007 0.0 13.0 13.0 0.92 0.01 538102.3 8462042.2
RRHA0008 0.0 5.0 5.0 0.93 537953.9 8461906.4
RRHA0019 0.0 5.0 5.0 0.85 537998.0 8462201.8
RRHA0021 0.0 4.0 4.0 0.91 537999.6 8461800.0
RRHA0034 0.0 2.0 2.0 0.83 537200.0 8462200.0
RRHA0041 0.0 10.0 10.0 0.93 538400.0 8462600.0
RRHA0055 0.0 4.0 4.0 0.86 537799.8 8461699.9
RRHA0057 0.0 4.0 4.0 1.04 538199.7 8462500.3
RRHA0058 7.0 13.0 6.0 0.76 538200.1 8462300.1
RRHA0059 0.0 5.0 5.0 0.90 538196.8 8462105.2
RRHA0060 0.0 9.0 9.0 0.77 538199.8 8461900.0
APPENDIX 3: DRILL HOLE COLLAR DATA
Drillhole Easting Northing Elevation Hole Type Depth Date Drilled Tenement
CHHA0001 559679.3 8518407.1 1094.1 HA 7 29/01/2021 EL0492
CHHA0002 560453.0 8518542.1 1108.8 HA 9 02/02/2021 EL0492
CHHA0003 561256.4 8518673.1 1124.3 HA 10 02/02/2021 EL0492
CHHA0004 562059.6 8518779.5 1120.8 HA 3 02/02/2021 EL0492
CHHA0005 559647.0 8517013.1 1094.3 HA 9 02/02/2021 EL0492
CHHA0006 560398.0 8516694.3 1103.9 HA 8 02/02/2021 EL0492
CHHA0007 561175.7 8516477.8 1119.9 HA 9 03/02/2021 EL0492
CHHA0008 561964.6 8516377.0 1132.9 HA 10 02/02/2021 EL0492
CHHA0009 566994.0 8513401.7 1115.1 HA 4 17/02/2021 EL0492
CHHA0010 567400.1 8513371.3 1108.6 HA 3 18/02/2021 EL0492
CHHA0011 567800.2 8513375.4 1122.2 HA 11 18/02/2021 EL0492
CHHA0012 568199.3 8513401.2 1125.4 HA 12 17/02/2021 EL0492
CHHA0013 568598.5 8513399.1 1119.5 HA 7 18/02/2021 EL0492
CHHA0014 568599.6 8510403.1 1150.5 HA 13 18/02/2021 EL0492
CHHA0015 568193.3 8510416.3 1149.2 HA 12 19/02/2021 EL0492
CHHA0016 567800.2 8510377.5 1146.3 HA 13 19/02/2021 EL0492
CHHA0017 566984.4 8510406.3 1132.4 HA 9 19/02/2021 EL0492
CHHA0018 567397.1 8510378.3 1140.4 HA 13 19/02/2021 EL0492
CHHA0019 566998.2 8506402.4 1161.4 HA 10 23/02/2021 EL0492
CHHA0020 567363.0 8506409.9 1166.2 HA 13 23/02/2021 EL0492
CHHA0021 567804.2 8506431.6 1169.5 HA 15 23/02/2021 EL0492
CHHA0022 568181.3 8506422.3 1166.5 HA 13 23/02/2021 EL0492
CHHA0023 568600.5 8506410.5 1158.8 HA 11 23/02/2021 EL0492
CHHA0024 566999.2 8504802.2 1169.0 HA 12 24/02/2021 EL0492
CHHA0025 567409.1 8504791.2 1166.4 HA 11 24/02/2021 EL0492
CHHA0026 567801.6 8504799.8 1161.3 HA 6 24/02/2021 EL0492
CHHA0027 568189.6 8504804.4 1154.2 HA 3 24/02/2021 EL0492
CHHA0028 569000.0 8504800.2 1156.0 HA 8 24/02/2021 EL0492
CHHA0029 569401.5 8504800.8 1160.6 HA 12 24/02/2021 EL0492
CHHA0030 569800.2 8504799.9 1160.5 HA 13 25/02/2021 EL0492
CHHA0031 570194.4 8504800.3 1153.3 HA 12 25/02/2021 EL0492
CHHA0032 569002.8 8503588.0 1170.4 HA 12 26/02/2021 EL0492
CHHA0037 570995.9 8503603.1 1171.3 HA 11 01/03/2021 EL0492
CHHA0038 570602.5 8503607.4 1166.0 HA 9 02/03/2021 EL0492
CHHA0039 570182.7 8503606.2 1155.0 HA 6 02/03/2021 EL0492
CHHA0040 569784.1 8503615.6 1154.6 HA 9 02/03/2021 EL0492
CHHA0041 569390.4 8503587.9 1167.5 HA 12 02/03/2021 EL0492
CHHA0042 567396.1 8502383.9 1187.0 HA 14 02/03/2021 EL0492
CHHA0043 567801.7 8502369.0 1193.1 HA 10 03/03/2021 EL0492
CHHA0044 568200.4 8502398.9 1191.2 HA 13 03/03/2021 EL0492
DWHA0001 534095.2 8479793.4 1051.2 HA 7 25/10/2022 EL0492
DWHA0002 534026.8 8479678.6 1057.1 HA 8 25/10/2022 EL0492
DWHA0003 533971.2 8479582.8 1062.1 HA 7 25/10/2022 EL0492
DWHA0004 534288.8 8480121.6 1049.9 HA 8 25/10/2022 EL0492
DWHA0005 534346.7 8480220.8 1050.2 HA 9 26/10/2022 EL0492
DWHA0006 534402.7 8480307.9 1055.9 HA 13 26/10/2022 EL0492
DWHA0007 534455.5 8480404.1 1059.6 HA 9 26/10/2022 EL0492
DWHA0008 534516.1 8480506.5 1061.7 HA 12 26/10/2022 EL0492
KYAC0021 544800.7 8471800.0 1131.9 AC 27 25/05/2022 EL0582
KYAC0041 544600.7 8472199.8 1131.5 AC 25 31/05/2022 EL0582
KYAC0063 543400.6 8471399.5 1117.2 AC 24 04/06/2022 EL0582
KYAC0083 543952.7 8468998.7 1128.7 AC 19 09/06/2022 EL0582
KYAC0103 549800.5 8479402.3 1125.7 AC 28 27/07/2022 EL0609
KYAC0123 548599.5 8478398.7 1139.1 AC 30 30/07/2022 EL0609
KYAC0143 544000.2 8468000.2 1141.4 AC 25.5 03/08/2022 EL0582
KYAC0163 545600.2 8464999.3 1168.8 AC 35 08/08/2022 EL0582
KYAC0183 546198.2 8467998.6 1160.9 AC 32 11/08/2022 EL0582
KYAC0192 546000.2 8464605.0 1173.0 AC 16 05/08/2024 EL0582
KYAC0193 546100.0 8464700.1 1171.9 AC 16 05/08/2024 EL0582
KYAC0194 546200.0 8464800.0 1170.0 AC 16 05/08/2024 EL0582
KYAC0195 546100.0 8464900.0 1169.9 AC 16 05/08/2024 EL0582
KYAC0196 545999.9 8465000.1 1169.5 AC 16 05/08/2024 EL0582
KYAC0197 545899.9 8464900.0 1170.7 AC 17 05/08/2024 EL0582
KYAC0198 545900.1 8464700.1 1172.1 AC 16 05/08/2024 EL0582
KYAC0199 545799.9 8464794.1 1171.3 AC 17 06/08/2024 EL0582
KYAC0200 545700.0 8464900.1 1169.9 AC 20 06/08/2024 EL0582
KYAC0201 545499.9 8464900.0 1168.1 AC 28 06/08/2024 EL0582
KYAC0202 545499.8 8464700.0 1168.4 AC 21 06/08/2024 EL0582
KYAC0203 545299.9 8464700.0 1164.4 AC 20 06/08/2024 EL0582
KYAC0204 545300.0 8464894.6 1164.4 AC 26 06/08/2024 EL0582
KYAC0205 545100.1 8464900.1 1160.2 AC 21 06/08/2024 EL0582
KYAC0206 545099.9 8465100.1 1161.9 AC 23 06/08/2024 EL0582
KYAC0207 545300.0 8465100.1 1165.1 AC 22 06/08/2024 EL0582
KYAC0208 545499.9 8465100.0 1167.4 AC 25 06/08/2024 EL0582
KYAC0209 545700.0 8465100.1 1168.8 AC 23 06/08/2024 EL0582
KYAC0210 545800.0 8465200.3 1168.2 AC 14 07/08/2024 EL0582
KYAC0211 545700.0 8465300.2 1167.5 AC 23 07/08/2024 EL0582
KYAC0212 545500.0 8465300.1 1166.6 AC 26 07/08/2024 EL0582
KYAC0213 545299.9 8465300.0 1165.1 AC 23 07/08/2024 EL0582
KYAC0214 545100.0 8465300.0 1162.7 AC 23 07/08/2024 EL0582
KYAC0215 544900.0 8465500.0 1161.4 AC 20 07/08/2024 EL0582
KYAC0216 545100.0 8465500.1 1162.5 AC 17 07/08/2024 EL0582
KYAC0217 545300.0 8465500.0 1163.9 AC 23 07/08/2024 EL0582
KYAC0218 545500.0 8465500.0 1164.9 AC 20 07/08/2024 EL0582
KYAC0219 545700.0 8465500.0 1164.8 AC 22 07/08/2024 EL0582
KYAC0220 545900.0 8465500.0 1164.1 AC 21 07/08/2024 EL0582
KYAC0221 546100.0 8465700.0 1157.2 AC 18 08/08/2024 EL0582
KYAC0222 545900.5 8465700.3 1160.3 AC 23 08/08/2024 EL0582
KYAC0223 545899.9 8465900.0 1154.8 AC 22 08/08/2024 EL0582
KYAC0224 545700.0 8465700.0 1161.7 AC 17 08/08/2024 EL0582
KYAC0225 545500.0 8465700.0 1161.7 AC 25 08/08/2024 EL0582
KYAC0226 545300.0 8465700.0 1161.8 AC 18 08/08/2024 EL0582
KYAC0227 545099.6 8465700.1 1161.2 AC 25 08/08/2024 EL0582
KYAC0228 545100.0 8465900.0 1158.8 AC 17 08/08/2024 EL0582
KYAC0229 544899.9 8465700.0 1161.0 AC 16 08/08/2024 EL0582
KYAC0230 544400.2 8466199.0 1158.0 AC 18 08/08/2024 EL0582
KYAC0231 544300.0 8466100.0 1157.6 AC 17 09/08/2024 EL0582
KYAC0232 544100.0 8466100.1 1155.0 AC 18 09/08/2024 EL0582
KYAC0233 544000.0 8466200.1 1153.3 AC 17 09/08/2024 EL0582
KYAC0234 543900.0 8466300.0 1152.1 AC 14 09/08/2024 EL0582
KYAC0235 544100.0 8466300.0 1155.1 AC 18 09/08/2024 EL0582
KYAC0236 544299.9 8466300.0 1156.8 AC 17 09/08/2024 EL0582
KYAC0237 544499.9 8466300.0 1157.2 AC 13 09/08/2024 EL0582
KYAC0238 544300.0 8466500.1 1156.4 AC 17 09/08/2024 EL0582
KYAC0239 544200.0 8466400.0 1156.4 AC 19 09/08/2024 EL0582
KYAC0240 544100.1 8466500.3 1154.9 AC 18 09/08/2024 EL0582
KYAC0241 543900.0 8466499.9 1151.7 AC 17 09/08/2024 EL0582
KYAC0242 543800.0 8466400.1 1149.8 AC 26 09/08/2024 EL0582
KYAC0243 544000.0 8466600.0 1153.0 AC 32 09/08/2024 EL0582
KYAC0244 543899.3 8466700.1 1150.8 AC 16 10/08/2024 EL0582
KYAC0245 544100.0 8466700.1 1153.6 AC 18 10/08/2024 EL0582
KYAC0246 544200.0 8466800.0 1153.4 AC 16 10/08/2024 EL0582
KYAC0247 544100.0 8466900.0 1151.7 AC 20 10/08/2024 EL0582
KYAC0248 543900.0 8466900.0 1148.9 AC 18 10/08/2024 EL0582
KYAC0249 544000.0 8467000.0 1149.2 AC 17 10/08/2024 EL0582
KYAC0250 544100.3 8467100.4 1149.6 AC 29 10/08/2024 EL0582
KYAC0251 544200.0 8467200.0 1149.4 AC 20 10/08/2024 EL0582
KYAC0252 544300.0 8467100.0 1150.5 AC 21 10/08/2024 EL0582
KYAC0253 544299.9 8467300.0 1148.7 AC 19 10/08/2024 EL0582
KYAC0254 546099.6 8467300.1 1161.9 AC 23 12/08/2024 EL0582
KYAC0255 546300.0 8467300.0 1165.4 AC 24 12/08/2024 EL0582
KYAC0256 546500.1 8467299.5 1168.1 AC 20 12/08/2024 EL0582
KYAC0257 546699.9 8467299.9 1169.7 AC 20 12/08/2024 EL0582
KYAC0258 546700.0 8467500.4 1170.6 AC 20 12/08/2024 EL0582
KYAC0259 546699.9 8467700.3 1169.5 AC 19 12/08/2024 EL0582
KYAC0260 546500.1 8467500.0 1169.4 AC 20 12/08/2024 EL0582
KYAC0261 546300.5 8467505.4 1166.6 AC 29 12/08/2024 EL0582
KYAC0262 546099.8 8467500.1 1163.3 AC 17 12/08/2024 EL0582
KYAC0263 545900.0 8467500.0 1159.7 AC 18 12/08/2024 EL0582
KYAC0264 545900.0 8467700.0 1158.9 AC 17 12/08/2024 EL0582
KYAC0265 546000.0 8467800.0 1159.4 AC 32 12/08/2024 EL0582
KYAC0266 546100.0 8467900.0 1160.0 AC 29 13/08/2024 EL0582
KYAC0267 546300.0 8467900.0 1164.0 AC 26 13/08/2024 EL0582
KYAC0268 546301.6 8468102.2 1161.5 AC 21 13/08/2024 EL0582
KYAC0269 546500.0 8468100.0 1163.9 AC 11.7 13/08/2024 EL0582
KYAC0270 546700.0 8468100.0 1164.2 AC 28 13/08/2024 EL0582
KYAC0271 546700.0 8467900.0 1167.0 AC 22 13/08/2024 EL0582
KYAC0272 546485.5 8467898.1 1166.7 AC 14.5 13/08/2024 EL0582
KYAC0273 546499.9 8467700.0 1168.6 AC 22 13/08/2024 EL0582
KYAC0274 546300.0 8467700.0 1166.1 AC 21 13/08/2024 EL0582
KYAC0275 546098.7 8467703.8 1162.4 AC 21 13/08/2024 EL0582
KYAC0276 544099.9 8467300.1 1147.5 AC 22 14/08/2024 EL0582
KYAC0277 543899.6 8467300.0 1144.9 AC 22.8 14/08/2024 EL0582
KYAC0278 543699.9 8467300.0 1141.8 AC 23 14/08/2024 EL0582
KYAC0279 543500.1 8467300.0 1136.6 AC 16 14/08/2024 EL0582
KYAC0280 543602.7 8467396.8 1138.9 AC 18.3 14/08/2024 EL0582
KYAC0281 543499.0 8467500.0 1134.1 AC 27.5 14/08/2024 EL0582
KYAC0282 543700.1 8467500.0 1140.0 AC 25 14/08/2024 EL0582
KYAC0283 543900.1 8467500.0 1143.5 AC 26 14/08/2024 EL0582
KYAC0284 544100.1 8467500.1 1145.4 AC 26 14/08/2024 EL0582
KYAC0285 544300.1 8467500.0 1146.4 AC 23 14/08/2024 EL0582
KYAC0286 544200.0 8467600.0 1145.4 AC 23 14/08/2024 EL0582
KYAC0287 544500.0 8467700.0 1144.3 AC 21 14/08/2024 EL0582
KYAC0288 544299.4 8467699.9 1145.5 AC 23 15/08/2024 EL0582
KYAC0289 544099.4 8467699.7 1144.4 AC 27.4 15/08/2024 EL0582
KYAC0290 543899.4 8467700.0 1142.4 AC 25 15/08/2024 EL0582
KYAC0291 543700.0 8467700.0 1139.2 AC 24 15/08/2024 EL0582
KYAC0292 543500.1 8467700.0 1131.6 AC 20 15/08/2024 EL0582
KYAC0293 543500.0 8467900.0 1130.1 AC 19.5 15/08/2024 EL0582
KYAC0294 543702.6 8467900.0 1137.4 AC 23 15/08/2024 EL0582
KYAC0295 543900.0 8467900.1 1141.5 AC 23 15/08/2024 EL0582
KYAC0296 544100.0 8467900.0 1143.2 AC 25 15/08/2024 EL0582
KYAC0297 544300.0 8467900.0 1144.1 AC 21 15/08/2024 EL0582
KYAC0298 544500.0 8467900.0 1143.2 AC 22 15/08/2024 EL0582
KYAC0299 544500.0 8468100.0 1141.7 AC 28 15/08/2024 EL0582
KYAC0300 544500.0 8468300.0 1140.6 AC 24 15/08/2024 EL0582
KYAC0301 544295.0 8468300.0 1141.4 AC 22 16/08/2024 EL0582
KYAC0302 544300.0 8468100.0 1142.4 AC 21.4 16/08/2024 EL0582
KYAC0303 544099.7 8468300.1 1139.7 AC 25 16/08/2024 EL0582
KYAC0304 543900.0 8468100.0 1139.4 AC 24 16/08/2024 EL0582
KYAC0305 543700.0 8468100.1 1134.3 AC 20 16/08/2024 EL0582
KYAC0306 543500.0 8468100.0 1127.5 AC 20 16/08/2024 EL0582
KYAC0307 543500.0 8468300.0 1125.5 AC 7 16/08/2024 EL0582
KYAC0308 543700.0 8468300.0 1130.4 AC 17 16/08/2024 EL0582
KYAC0309 543900.0 8468300.0 1137.1 AC 18 16/08/2024 EL0582
KYAC0310 543900.0 8468500.0 1132.8 AC 18 16/08/2024 EL0582
KYAC0311 543497.7 8468499.1 1122.9 AC 19 17/08/2024 EL0582
KYAC0312 543603.5 8468600.6 1124.0 AC 16 17/08/2024 EL0582
KYAC0313 543700.0 8468706.0 1124.1 AC 13 17/08/2024 EL0582
KYAC0314 543699.9 8468504.9 1127.5 AC 23 17/08/2024 EL0582
KYAC0315 544099.9 8468500.1 1137.9 AC 24 17/08/2024 EL0582
KYAC0316 544300.1 8468500.0 1139.5 AC 18 17/08/2024 EL0582
KYAC0317 544499.8 8468500.0 1139.3 AC 22 17/08/2024 EL0582
KYAC0318 544700.0 8468500.1 1136.4 AC 21 17/08/2024 EL0582
KYAC0319 544699.9 8468699.9 1134.7 AC 31 17/08/2024 EL0582
KYAC0320 544499.9 8468700.0 1137.4 AC 26 17/08/2024 EL0582
KYAC0321 544300.0 8468700.2 1137.9 AC 23 19/08/2024 EL0582
KYAC0322 544300.0 8468900.1 1136.7 AC 21 19/08/2024 EL0582
KYAC0323 544499.9 8468900.0 1136.0 AC 38 19/08/2024 EL0582
KYAC0324 544700.1 8468900.6 1133.2 AC 29 19/08/2024 EL0582
KYAC0325 544600.1 8469200.0 1133.4 AC 21 19/08/2024 EL0582
KYAC0326 544500.0 8469300.2 1133.7 AC 21 19/08/2024 EL0582
KYAC0327 544500.1 8469100.1 1135.1 AC 23 19/08/2024 EL0582
KYAC0328 544299.9 8469100.0 1135.4 AC 20 19/08/2024 EL0582
KYAC0329 544299.4 8469299.9 1134.3 AC 23 19/08/2024 EL0582
KYAC0330 544094.4 8469505.1 1130.5 AC 26 19/08/2024 EL0582
KYAC0331 544199.9 8469600.0 1131.2 AC 14.7 19/08/2024 EL0582
KYAC0332 544099.9 8469700.0 1129.3 AC 15.7 19/08/2024 EL0582
KYAC0333 544000.0 8469799.9 1126.6 AC 16 20/08/2024 EL0582
KYAC0334 543899.9 8469700.0 1123.2 AC 25 20/08/2024 EL0582
KYAC0335 543799.8 8469600.0 1119.0 AC 15 20/08/2024 EL0582
KYAC0336 543701.1 8469507.2 1114.8 AC 10 20/08/2024 EL0582
KYAC0337 543700.0 8469299.9 1116.2 AC 14 20/08/2024 EL0582
KYAC0338 543899.9 8469899.9 1122.4 AC 26 20/08/2024 EL0582
KYAC0339 543720.5 8469900.1 1114.6 AC 12 20/08/2024 EL0582
KYAC0340 543739.5 8469700.1 1115.7 AC 14 20/08/2024 EL0582
KYAC0341 543800.0 8470000.1 1117.3 AC 21 20/08/2024 EL0582
KYAC0342 543700.0 8470100.0 1114.1 AC 14 20/08/2024 EL0582
KYAC0343 543900.0 8470100.0 1122.8 AC 22 20/08/2024 EL0582
KYAC0344 543999.9 8470200.2 1125.4 AC 21 20/08/2024 EL0582
KYAC0345 544100.0 8470300.1 1126.9 AC 23 21/08/2024 EL0582
KYAC0346 543899.8 8470300.1 1122.5 AC 18 21/08/2024 EL0582
KYAC0347 544099.9 8470500.1 1125.8 AC 24 21/08/2024 EL0582
KYAC0348 544300.0 8470700.0 1123.6 AC 26 21/08/2024 EL0582
KYAC0349 544300.0 8470900.1 1122.2 AC 24 21/08/2024 EL0582
KYAC0350 544099.9 8470700.2 1124.5 AC 21 21/08/2024 EL0582
KYAC0351 544099.8 8470900.1 1122.3 AC 16 21/08/2024 EL0582
KYAC0352 544100.3 8471100.0 1117.5 AC 11 21/08/2024 EL0582
KYAC0353 543899.8 8471100.0 1114.5 AC 20 21/08/2024 EL0582
KYAC0354 543900.0 8470900.0 1119.6 AC 16 21/08/2024 EL0582
KYAC0355 543805.2 8470800.0 1118.7 AC 13 21/08/2024 EL0582
KYAC0356 543900.0 8470700.0 1121.5 AC 20 21/08/2024 EL0582
KYAC0357 543899.9 8470499.9 1122.8 AC 23 22/08/2024 EL0582
KYAC0358 543799.9 8470400.1 1119.5 AC 22 22/08/2024 EL0582
KYAC0359 543699.9 8470300.0 1114.7 AC 11 22/08/2024 EL0582
KYAC0360 543600.0 8470204.0 1109.7 AC 8 22/08/2024 EL0582
KYAC0361 543499.9 8469499.9 1117.8 AC 9 22/08/2024 EL0582
KYAC0362 543576.0 8469400.1 1114.0 AC 8 22/08/2024 EL0582
KYAC0363 543300.0 8469497.3 1124.4 AC 15 22/08/2024 EL0582
KYAC0364 543100.0 8469500.1 1128.9 AC 20 22/08/2024 EL0582
KYAC0365 543000.0 8469599.9 1129.9 AC 26 22/08/2024 EL0582
KYAC0366 542900.1 8469700.1 1130.2 AC 23 22/08/2024 EL0582
KYAC0367 543100.0 8469700.1 1127.8 AC 18 23/08/2024 EL0582
KYAC0368 543300.2 8469700.0 1123.6 AC 20 23/08/2024 EL0582
KYAC0369 543400.0 8469600.0 1121.3 AC 14 23/08/2024 EL0582
KYAC0370 543505.6 8469703.0 1116.0 AC 11 23/08/2024 EL0582
KYAC0371 543572.5 8469799.7 1111.6 AC 5 23/08/2024 EL0582
KYAC0372 543499.9 8469900.2 1114.0 AC 8 23/08/2024 EL0582
KYAC0373 543299.7 8469900.0 1121.9 AC 17 23/08/2024 EL0582
KYAC0374 543199.9 8469799.9 1125.0 AC 16 23/08/2024 EL0582
KYAC0375 543100.1 8469900.1 1126.1 AC 29 23/08/2024 EL0582
KYAC0376 542903.1 8469900.0 1128.1 AC 19 23/08/2024 EL0582
KYAC0377 542807.6 8469799.9 1129.2 AC 21 23/08/2024 EL0582
KYAC0378 542700.0 8469899.8 1128.6 AC 15 23/08/2024 EL0582
KYAC0379 543000.0 8470000.1 1126.1 AC 24 23/08/2024 EL0582
KYAC0380 542900.0 8470099.9 1124.8 AC 18 24/08/2024 EL0582
KYAC0381 542800.1 8470200.0 1123.4 AC 18 24/08/2024 EL0582
KYAC0382 542900.0 8470299.9 1121.6 AC 18 24/08/2024 EL0582
KYAC0383 543000.0 8470399.9 1118.0 AC 19 24/08/2024 EL0582
KYAC0384 543099.9 8470501.8 1114.2 AC 20 24/08/2024 EL0582
KYAC0385 543099.9 8470300.5 1120.3 AC 17 24/08/2024 EL0582
KYAC0386 543300.0 8470299.9 1116.0 AC 17 24/08/2024 EL0582
KYAC0387 543499.9 8470300.0 1108.5 AC 11 24/08/2024 EL0582
KYAC0388 543501.8 8470099.8 1111.0 AC 7 24/08/2024 EL0582
KYAC0389 543544.2 8470000.3 1110.3 AC 10 24/08/2024 EL0582
KYAC0390 543400.2 8470000.2 1117.2 AC 16.5 24/08/2024 EL0582
KYAC0391 543299.9 8470100.0 1119.5 AC 19 24/08/2024 EL0582
KYAC0392 543199.9 8470200.0 1120.6 AC 21 24/08/2024 EL0582
KYAC0393 543100.1 8470100.5 1123.5 AC 22 24/08/2024 EL0582
KYAC0394 543299.8 8471500.0 1118.4 AC 22.5 26/08/2024 EL0582
KYAC0395 543200.1 8471400.1 1116.1 AC 18 26/08/2024 EL0582
KYAC0396 543100.1 8471300.0 1113.2 AC 17 26/08/2024 EL0582
KYAC0397 543100.0 8471102.0 1108.9 AC 17 27/08/2024 EL0582
KYAC0398 543200.0 8471000.0 1105.9 AC 12 27/08/2024 EL0582
KYAC0399 543300.1 8471100.1 1109.2 AC 12 27/08/2024 EL0582
KYAC0400 543300.0 8471300.0 1115.3 AC 22 27/08/2024 EL0582
KYAC0401 543500.1 8471300.1 1113.3 AC 13 27/08/2024 EL0582
KYAC0402 543700.1 8471299.9 1110.5 AC 10 27/08/2024 EL0582
KYAC0403 543700.0 8471500.1 1119.0 AC 14 27/08/2024 EL0582
KYAC0404 543499.9 8471500.1 1119.6 AC 21 27/08/2024 EL0582
KYAC0405 543098.8 8471700.1 1115.1 AC 21 27/08/2024 EL0582
KYAC0406 543200.0 8471800.1 1118.4 AC 14 27/08/2024 EL0582
KYAC0407 543300.3 8471700.0 1119.8 AC 22 27/08/2024 EL0582
KYAC0408 543499.7 8471700.0 1121.8 AC 23 27/08/2024 EL0582
KYAC0409 543700.0 8471700.1 1123.2 AC 30 27/08/2024 EL0582
KYAC0410 543900.1 8471700.0 1123.0 AC 20 28/08/2024 EL0582
KYAC0411 544100.0 8471700.0 1124.4 AC 19 28/08/2024 EL0582
KYAC0412 544300.1 8471700.1 1125.5 AC 19 28/08/2024 EL0582
KYAC0413 544300.1 8471500.0 1119.5 AC 16 28/08/2024 EL0582
KYAC0414 544500.0 8471500.0 1123.2 AC 19 28/08/2024 EL0582
KYAC0415 544699.7 8471500.0 1126.0 AC 19 28/08/2024 EL0582
KYAC0416 544501.9 8471700.3 1127.8 AC 18 28/08/2024 EL0582
KYAC0417 544699.9 8471700.2 1130.0 AC 21 28/08/2024 EL0582
KYAC0418 544900.0 8471700.0 1132.3 AC 24 28/08/2024 EL0582
KYAC0419 544899.9 8471900.0 1133.5 AC 26 28/08/2024 EL0582
KYAC0420 544899.7 8472100.4 1133.9 AC 19 28/08/2024 EL0582
KYAC0421 544800.2 8472199.9 1133.3 AC 21 28/08/2024 EL0582
KYAC0422 544700.3 8472100.3 1132.6 AC 23 29/08/2024 EL0582
KYAC0423 544699.5 8471899.9 1132.0 AC 24 29/08/2024 EL0582
KYAC0424 544500.6 8471899.6 1130.0 AC 22 29/08/2024 EL0582
KYAC0425 544500.0 8472100.0 1130.4 AC 25 29/08/2024 EL0582
KYAC0426 544500.0 8472300.1 1129.7 AC 20.5 29/08/2024 EL0582
KYAC0427 544299.7 8472300.0 1126.9 AC 19 29/08/2024 EL0582
KYAC0428 544300.0 8472098.4 1127.8 AC 7 29/08/2024 EL0582
KYAC0429 544300.1 8471900.0 1128.1 AC 19 29/08/2024 EL0582
KYAC0430 544100.0 8471899.9 1126.5 AC 16 30/08/2024 EL0582
KYAC0431 543900.2 8471899.5 1124.7 AC 21 30/08/2024 EL0582
KYAC0432 543700.4 8471900.4 1124.1 AC 22 30/08/2024 EL0582
KYAC0433 543499.7 8471899.7 1122.5 AC 10 30/08/2024 EL0582
KYAC0434 543300.0 8471899.9 1120.6 AC 16.6 30/08/2024 EL0582
KYAC0435 543100.0 8471900.0 1115.9 AC 9.5 30/08/2024 EL0582
KYAC0436 543100.0 8472100.0 1116.0 AC 18 30/08/2024 EL0609
KYAC0437 543299.9 8472100.0 1120.7 AC 18 30/08/2024 EL0609
KYAC0438 543500.1 8472100.0 1121.1 AC 26 30/08/2024 EL0609
KYAC0439 543699.9 8472100.0 1122.2 AC 27 30/08/2024 EL0609
KYAC0440 543700.1 8472300.0 1118.7 AC 19 30/08/2024 EL0609
KYAC0441 543499.9 8472299.9 1117.8 AC 21 30/08/2024 EL0609
KYAC0442 543299.5 8472300.1 1117.8 AC 22.4 31/08/2024 EL0609
KYAC0443 543397.4 8472401.3 1115.7 AC 12 31/08/2024 EL0609
KYAC0444 543299.6 8472499.0 1112.6 AC 12 31/08/2024 EL0609
KYAC0445 547399.6 8467001.0 1172.1 AC 22.5 02/09/2024 EL0582
KYAC0446 547202.1 8466999.9 1169.2 AC 29 02/09/2024 EL0582
KYAC0447 547399.9 8467200.1 1170.4 AC 16 02/09/2024 EL0582
KYAC0448 547000.0 8467199.8 1168.4 AC 32 02/09/2024 EL0582
KYAC0449 547200.0 8467400.0 1167.7 AC 28 02/09/2024 EL0582
KYAC0450 547000.0 8467599.9 1167.6 AC 32 02/09/2024 EL0582
KYAC0451 547200.0 8467800.0 1163.2 AC 24 02/09/2024 EL0582
KYAC0452 547000.0 8467900.0 1165.3 AC 23 02/09/2024 EL0582
KYAC0453 547000.0 8468100.0 1163.0 AC 26 02/09/2024 EL0582
KYAC0454 546804.2 8467802.1 1167.7 AC 22 02/09/2024 EL0582
KYAC0455 544300.5 8468120.6 1142.2 AC 20 03/09/2024 EL0582
KYAC0456 544280.5 8468105.5 1142.4 AC 19 03/09/2024 EL0582
KYAC0457 544260.7 8468105.6 1142.6 AC 20 03/09/2024 EL0582
KYAC0458 544240.2 8468106.2 1142.4 AC 21 03/09/2024 EL0582
KYAC0459 544220.1 8468105.9 1142.4 AC 20 03/09/2024 EL0582
KYAC0460 544200.1 8468106.7 1142.1 AC 21 03/09/2024 EL0582
KYAC0461 544179.9 8468105.5 1141.9 AC 22 03/09/2024 EL0582
KYAC0462 544160.0 8468106.0 1141.9 AC 22 03/09/2024 EL0582
KYAC0463 544139.9 8468105.5 1141.6 AC 22 03/09/2024 EL0582
KYAC0464 544110.1 8468120.8 1141.5 AC 19 03/09/2024 EL0582
KYAC0465 544302.5 8468280.2 1141.5 AC 23 03/09/2024 EL0582
KYAC0466 544300.1 8468260.6 1141.6 AC 22 04/09/2024 EL0582
KYAC0467 544299.3 8468240.8 1141.8 AC 25 04/09/2024 EL0582
KYAC0468 544300.0 8468219.9 1141.9 AC 25 04/09/2024 EL0582
KYAC0469 544299.9 8468199.9 1141.8 AC 21 04/09/2024 EL0582
KYAC0470 544299.9 8468179.9 1141.9 AC 20 04/09/2024 EL0582
KYAC0471 544300.1 8468159.8 1142.0 AC 20 04/09/2024 EL0582
KYAC0472 544299.9 8468139.9 1142.0 AC 18 04/09/2024 EL0582
KYAC0473 543699.86 8471900.6 1124.1 AC 22 06/06/2025 EL0582/20R2
KYAC0474 543600.62 8472000.2 1122.594 AC 27 06/06/2025 EL0609
KYAC0475 546399.17 8467599.7 1167.865 AC 21 01/07/2025 EL0582/20R2
KYAC0476 546301.67 8467505.1 1166.625 AC 29 02/07/2025 EL0582/20R2
KYAC0477 545500.74 8465500 1164.898 AC 20 03/07/2025 EL0582/20R2
KYAC0478 545599.53 8465399.6 1166.384 AC 29 04/07/2025 EL0582/20R2
KYAC0479 543498.61 8471501.6 1119.65 AC 20 04/08/2025 EL0582/20R2
KYAC0480 543299.03 8472101.2 1120.678 AC 18.2 04/08/2025 EL0609
KYAC0481 544299.38 8471700 1125.489 AC 19 04/08/2025 EL0582/20R2
KYAC0482 544700.45 8472099.3 1132.546 AC 20 06/08/2025 EL0582/20R2
KYAC0483 543200.08 8470200.4 1120.604 AC 20 08/08/2025 EL0582/20R2
KYAC0484 543100.38 8469900.9 1126.02 AC 20 09/08/2025 EL0582/20R2
KYAC0485 543399.79 8469600.7 1121.313 AC 13.64 11/08/2025 EL0582/20R2
KYAC0486 543900.23 8468101 1139.349 AC 20 11/08/2025 EL0582/20R2
KYAC0487 544499.77 8468699 1137.403 AC 20 13/08/2025 EL0582/20R2
KYAC0488 544900.2 8472099.1 1133.895 AC 19 19/09/2025 EL0582/20R2
KYAC0489 544800.16 8472200.9 1133.233 AC 21.5 19/09/2025 EL0582/20R2
KYAC0490 544900.49 8472300.4 1133.096 AC 16 19/09/2025 EL0582/20R2
KYAC0491 545100.1 8472099.6 1131.903 AC 6.18 19/09/2025 EL0582/20R2
KYAC0492 544999.99 8472400.1 1132.187 AC 13.1 20/09/2025 EL0582/20R2
KYAC0493 544900.04 8472500 1130.194 AC 17 20/09/2025 EL0582/20R2
KYAC0494 544700.13 8472500 1128.909 AC 18 20/09/2025 EL0582/20R2
KYAC0495 544600.5 8472400.4 1129.866 AC 10.38 20/09/2025 EL0582/20R2
KYAC0496 544700.01 8472299 1132.13 AC 20.3 20/09/2025 EL0582/20R2
KYAC0497 544501.1 8472300 1129.715 AC 14.74 22/09/2025 EL0582/20R2
KYAC0499 544499.6 8472098 1130.372 AC 23.65 22/09/2025 EL0582/20R2
KYAC0500 543099.1 8472300 1114.368 AC 18 22/09/2025 EL0609
KYAC0501 543098.83 8472100.4 1115.961 AC 18.82 23/09/2025 EL0609
KYAC0502 542998.85 8472000 1112.19 AC 20 23/09/2025 EL0582/20R2
KYAC0503 542899.09 8472100.2 1107.467 AC 19 23/09/2025 EL0609
KYAC0504 542899.83 8472299.4 1106.337 AC 11 23/09/2025 EL0609
KYAC0505 543499.8 8472098 1121.142 AC 24 25/09/2025 EL0609
KYAC0506 543700.2 8472101 1122.23 AC 26.45 25/09/2025 EL0609
KYAC0507 543299.8 8471901.1 1120.614 AC 13.55 26/09/2025 EL0582/20R2
KYAC0508 543098.9 8471899.5 1115.862 AC 10.88 26/09/2025 EL0582/20R2
KYAC0509 543300.9 8472299.9 1117.75 AC 18.1 26/09/2025 EL0609
KYAC0510 544100.19 8472099.4 1126.162 AC 23.76 28/09/2025 EL0582/20R2
KYAC0511 544798.08 8468999.9 1129.268 AC 14.83 30/09/2025 EL0582/20R2
KYAC0512 544700.06 8468901.1 1133.165 AC 28 01/10/2025 EL0582/20R2
KYAC0513 544499.58 8468900.4 1136.029 AC 28 01/10/2025 EL0582/20R2
KYAC0514 544700.78 8468700 1134.652 AC 28 02/10/2025 EL0582/20R2
KYAC0515 544698.78 8468500.1 1136.496 AC 18 02/10/2025 EL0582/20R2
KYAC0516 544499.81 8468501 1139.271 AC 23 07/10/2025 EL0582/20R2
KYAC0517 544500.73 8468300.2 1140.573 AC 24 07/10/2025 EL0582/20R2
KYAC0518 544500.09 8468100.8 1141.661 AC 28 08/10/2025 EL0582/20R2
KYAC0519 544300.02 8468701 1137.893 AC 23 08/10/2025 EL0582/20R2
KYAC0520 544300.06 8468499.1 1139.457 AC 18 08/10/2025 EL0582/20R2
KYAC0521 544293.85 8468300.4 1141.364 AC 21.7 09/10/2025 EL0582/20R2
KYAC0522 544100.54 8468301.3 1139.734 AC 25 09/10/2025 EL0582/20R2
KYAC0523 544102.94 8468099.9 1141.546 AC 19 09/10/2025 EL0582/20R2
KYAC0524 544099.37 8468500.1 1137.861 AC 24 09/10/2025 EL0582/20R2
KYAC0525 543699.26 8468100 1134.295 AC 19.75 10/10/2025 EL0582/20R2
KYAC0526 543699.95 8467897 1137.463 AC 22 10/10/2025 EL0582/20R2
KYAC0527 543898.97 8467700.1 1142.342 AC 23 10/10/2025 EL0582/20R2
KYAC0528 544099.28 8467699.8 1144.395 AC 26 11/10/2025 EL0582/20R2
KYAC0529 544299.03 8467700 1145.508 AC 22 11/10/2025 EL0582/20R2
KYAC0530 544099.2 8467900 1143.196 AC 25 11/10/2025 EL0582/20R2
KYAC0531 544199.23 8467599.9 1145.413 AC 24 11/10/2025 EL0582/20R2
KYAC0532 544499.3 8467499.9 1145.97 AC 17.62 12/10/2025 EL0582/20R2
KYAC0533 544601.07 8467600.1 1144.573 AC 18 12/10/2025 EL0582/20R2
KYAC0534 544501.06 8467700 1144.323 AC 21 12/10/2025 EL0582/20R2
KYDD0001 544499.1 8467899.8 1143.2 PTDD 28 21/08/2024 EL0582
KYDD0002 543498.9 8468099.9 1127.5 PTDD 20.12 24/08/2024 EL0582
KYDD0003 543699.0 8467700.0 1139.2 PTDD 24.6 27/08/2024 EL0582
KYDD0004 544301.2 8468099.8 1142.5 PTDD 21.15 29/08/2024 EL0582
KYDD0005 543900.9 8467499.4 1143.6 PTDD 22.15 31/08/2024 EL0582
KYDD0006 544200.6 8466800.4 1153.4 PTDD 18.54 03/09/2024 EL0582
KYDD0007 544301.0 8466500.0 1156.4 PTDD 19.59 05/09/2024 EL0582
KYDD0008 543900.2 8466300.1 1152.2 PTDD 23.87 06/09/2024 EL0582
KYDD0009 545301.1 8465700.3 1161.8 PTDD 20.08 07/09/2024 EL0582
KYDD0010 545699.0 8465499.7 1164.9 PTDD 37.15 09/09/2024 EL0582
KYDD0011 545299.8 8465100.9 1165.1 PTDD 24.17 11/09/2024 EL0582
KYDD0012 546099.9 8464901.0 1169.9 PTDD 23.99 12/09/2024 EL0582
KYDD0013 544299.7 8472099.4 1127.8 PTDD 23.49 14/09/2024 EL0582
KYDD0014 543899.8 8471900.3 1124.7 PTDD 20.57 16/09/2024 EL0582
KYDD0015 544700.8 8471499.5 1126.0 PTDD 25.12 17/09/2024 EL0582
KYDD0016 543501.1 8472300.1 1117.8 PTDD 21.07 18/09/2024 EL0609
KYDD0017 543397.2 8472402.0 1115.7 PTDD 13.12 19/09/2024 EL0609
KYDD0018 543300.2 8471700.8 1119.9 PTDD 23.1 21/09/2024 EL0582
KYDD0019 543098.2 8471699.8 1115.1 PTDD 30.12 23/09/2024 EL0582
KYDD0020 542899.9 8470101.0 1124.8 PTDD 17.05 24/09/2024 EL0582
KYDD0021 543400.0 8470000.9 1117.2 PTDD 16.81 25/09/2024 EL0582
KYDD0022 543300.4 8469700.8 1123.6 PTDD 22.92 26/09/2024 EL0582
KYDD0023 544299.8 8470901.3 1122.2 PTDD 22.1 28/09/2024 EL0582
KYDD0024 543899.8 8470499.3 1122.8 PTDD 23.46 30/09/2024 EL0582
KYDD0025 543799.9 8470001.2 1117.3 PTDD 18.68 02/10/2024 EL0582
KYDD0026 543899.9 8469701.0 1123.2 PTDD 21 03/10/2024 EL0582
KYDD0027 544300.2 8468900.9 1136.7 PTDD 21.66 04/10/2024 EL0582
KYDD0028 546100.2 8467301.1 1161.9 PTDD 31.14 05/10/2024 EL0582
KYDD0029 546485.2 8467899.3 1166.7 PTDD 17.09 08/10/2024 EL0582
KYDD0030 546098.7 8467705.1 1162.3 PTDD 20.89 08/10/2024 EL0582
KYHA0002 547762.1 8480191.5 1147.4 HA 10 14/08/2019 EL0609
KYHA0004 548175.8 8480269.9 1144.4 HA 15 14/08/2019 EL0609
KYHA0008 549019.9 8480440.8 1129.2 HA 6 15/08/2019 EL0609
KYHA0009 549370.7 8480494.9 1128.6 HA 6 15/08/2019 EL0609
KYHA0011 549788.7 8480594.5 1127.6 HA 12 15/08/2019 EL0609
KYHA0023 538598.2 8478202.8 1072.7 HA 14 17/12/2019 EL0609
KYHA0035 538799.7 8479200.4 1090.7 HA 10 19/12/2019 EL0609
KYHA0054 537598.8 8477602.3 1084.9 HA 11 22/01/2020 EL0492
KYHA0055 537999.6 8477626.7 1076.3 HA 9.5 22/01/2020 EL0609
KYHA0061 538790.0 8478777.6 1080.0 HA 11 23/01/2020 EL0609
KYHA0065 539994.3 8479196.7 1093.1 HA 9 22/01/2020 EL0609
KYHA0066 539599.8 8479167.4 1093.8 HA 15 22/01/2020 EL0609
KYHA0078 541193.6 8481599.6 1109.5 HA 10 28/02/2020 EL0609
KYHA0080 541998.9 8481598.6 1112.6 HA 2 29/02/2020 EL0609
KYHA0087 540807.4 8479997.7 1101.2 HA 8 01/03/2020 EL0609
KYHA0099 541999.8 8479195.6 1116.5 HA 9 07/03/2020 EL0609
KYHA0105 539192.1 8477994.6 1081.2 HA 14 08/03/2020 EL0609
KYHA0120 539599.5 8479167.7 1093.8 HA 14 19/03/2020 EL0609
KYHA0123 539993.0 8479995.0 1097.9 HA 11 20/03/2020 EL0609
KYHA0126 540001.2 8481200.8 1099.0 HA 11 21/03/2020 EL0609
KYHA0133 537199.6 8477200.6 1091.7 HA 10 24/03/2020 EL0492
KYHA0142 540798.9 8478800.1 1108.3 HA 16 26/03/2020 EL0609
KYHA0157 544029.0 8480381.5 1146.1 HA 10 03/04/2020 EL0609
KYHA0161 543207.2 8482409.4 1123.1 HA 7 06/04/2020 EL0609
KYHA0163 542455.0 8481633.3 1115.5 HA 4 06/04/2020 EL0609
KYHA0164 543166.7 8481571.8 1129.5 HA 11 06/04/2020 EL0609
KYHA0171 542401.2 8480000.8 1125.2 HA 10 08/04/2020 EL0609
KYHA0177 543243.3 8478790.4 1134.8 HA 11 11/04/2020 EL0609
KYHA0178 542399.4 8478000.9 1108.2 HA 8 11/04/2020 EL0609
KYHA0182 540199.3 8479599.0 1101.7 HA 12 22/04/2020 EL0609
KYHA0184 540998.4 8479605.4 1109.1 HA 11 23/04/2020 EL0609
KYHA0200 541800.0 8479200.0 1116.8 HA 8 28/04/2020 EL0609
KYHA0202 539398.6 8479198.0 1094.2 HA 13 29/04/2020 EL0609
KYHA0235 541200.5 8478001.0 1105.8 HA 15 07/05/2020 EL0609
KYHA0240 541600.6 8480399.8 1101.9 HA 3 08/05/2020 EL0609
KYHA0246 540798.7 8480799.7 1094.4 HA 9 09/05/2020 EL0609
KYHA0256 537599.0 8477602.1 1084.9 HA 11 13/05/2020 EL0492
KYHA0256 537599.0 8477602.1 1084.9 HA 11 13/05/2020 EL0609
KYHA0257 538598.1 8478202.5 1072.8 HA 14 14/05/2020 EL0609
KYHA0258 538789.7 8478777.3 1080.0 HA 11 14/05/2020 EL0609
KYHA0259 539598.7 8479601.1 1098.7 HA 11 14/05/2020 EL0609
KYHA0260 539600.7 8480400.5 1085.9 HA 10 14/05/2020 EL0609
KYHA0261 540001.6 8481200.7 1099.0 HA 10 14/05/2020 EL0609
KYHA0262 541193.5 8481600.0 1109.5 HA 10 14/05/2020 EL0609
KYHA0278 543199.2 8477199.8 1108.6 HA 7 18/06/2020 EL0609
KYHA0292 537600.9 8478798.8 1063.7 HA 8 01/07/2020 EL0492
KYHA0294 541599.6 8477598.4 1096.3 HA 7 02/07/2020 EL0609
KYHA0308 541200.0 8482000.0 1111.1 HA 4 05/07/2020 EL0609
KYHA0315 542812.2 8479976.7 1128.5 HA 9 04/07/2020 EL0609
KYHA0317 542800.1 8480800.0 1121.7 HA 4 04/07/2020 EL0609
KYHA0328 543199.0 8481200.3 1123.9 HA 4 07/07/2020 EL0609
KYHA0330 542800.1 8481199.8 1115.9 HA 10 07/07/2020 EL0609
KYHA0342 543599.4 8482799.2 1122.9 HA 12 09/07/2020 EL0609
KYHA0343 544002.6 8482800.0 1124.6 HA 5 09/07/2020 EL0609
KYHA0399 542400.0 8477200.8 1098.8 HA 2 29/09/2020 EL0609
KYHA0406 540415.0 8476800.0 1078.1 HA 7 03/10/2020 EL0609
KYHA0425 543600.1 8477200.0 1119.0 HA 5 05/10/2020 EL0609
KYHA0451 544799.9 8476400.0 1115.5 HA 3 14/10/2020 EL0609
KYHA0456 544000.0 8476400.0 1112.2 HA 4 16/10/2020 EL0609
KYHA0539 540200.4 8479198.6 1096.2 HA 11 18/06/2021 EL0609
KYHA0540 539649.5 8477991.5 1068.5 HA 8 18/06/2021 EL0609
KYHA0542 542000.3 8476800.9 1099.2 HA 12 19/06/2021 EL0609
KYHA0545 541996.4 8479997.9 1115.4 HA 5 22/06/2021 EL0609
KYHA0546 541603.1 8480002.7 1105.2 HA 5 22/06/2021 EL0609
KYHA0551 542002.4 8478802.2 1112.1 HA 7 23/06/2021 EL0609
KYHA0565 542400.5 8480001.3 1125.2 HA 3 28/06/2021 EL0609
KYHA0568 540596.9 8479200.4 1105.5 HA 12 29/06/2021 EL0609
KYHA0571 540900.6 8476854.4 1076.0 HA 6 29/06/2021 EL0609
KYHA0574 542400.6 8479601.1 1122.4 HA 12 30/06/2021 EL0609
KYHA0575 541994.3 8477598.2 1093.6 HA 6 30/06/2021 EL0609
KYHA0578 543197.6 8482793.6 1115.3 HA 10 30/06/2021 EL0609
KYHA0579 542400.8 8476798.8 1106.0 HA 3 01/07/2021 EL0609
KYHA0580 543998.9 8477999.2 1129.2 HA 1 01/07/2021 EL0609
KYHA0581 544000.1 8478799.1 1144.8 HA 3 01/07/2021 EL0609
KYHA0582 545202.6 8476399.9 1125.4 HA 11 01/07/2021 EL0609
KYHA0804 549198.9 8479601.8 1132.3 HA 11 03/11/2021 EL0609
KYHA0811 548798.8 8479197.9 1138.6 HA 12 04/11/2021 EL0609
KYHA0818 548398.8 8478798.4 1144.4 HA 12 04/11/2021 EL0609
KYHA0837 548799.3 8478401.7 1136.9 HA 12 09/11/2021 EL0609
KYHA0838 548399.6 8478399.1 1141.4 HA 12 09/11/2021 EL0609
KYHA0898 539200.6 8480203.0 1088.5 HA 11 23/11/2021 EL0609
KYHA0899 539606.6 8480200.3 1091.6 HA 12 23/11/2021 EL0609
KYHA0900 540000.9 8480199.9 1094.7 HA 12 23/11/2021 EL0609
KYHA0901 539204.2 8479800.8 1094.9 HA 13 23/11/2021 EL0609
KYHA0902 539601.7 8479802.0 1097.9 HA 11 23/11/2021 EL0609
KYHA0903 540001.5 8479800.5 1100.0 HA 13 23/11/2021 EL0609
KYHA0904 539199.8 8479402.0 1096.3 HA 12 23/11/2021 EL0609
KYHA0905 539598.7 8479403.0 1097.7 HA 13 23/11/2021 EL0609
KYHA0906 540400.7 8479803.0 1102.6 HA 13 23/11/2021 EL0609
KYHA0907 540402.9 8479402.0 1102.4 HA 13 23/11/2021 EL0609
KYHA0908 540801.9 8479806.6 1105.6 HA 12 24/11/2021 EL0609
KYHA0909 541202.9 8479802.7 1107.3 HA 10 24/11/2021 EL0609
KYHA0910 541600.5 8479795.2 1109.5 HA 7 24/11/2021 EL0609
KYHA0911 541799.6 8479602.8 1116.4 HA 10 24/11/2021 EL0609
KYHA0912 541200.7 8479401.7 1113.5 HA 12 24/11/2021 EL0609
KYHA0913 541603.4 8479403.3 1116.7 HA 12 24/11/2021 EL0609
KYHA0914 540799.5 8479001.5 1108.9 HA 12 24/11/2021 EL0609
KYHA0915 541203.3 8479000.6 1115.3 HA 12 24/11/2021 EL0609
KYHA0916 542200.8 8479606.1 1121.2 HA 12 25/11/2021 EL0609
KYHA0917 542600.8 8479605.0 1122.3 HA 8 25/11/2021 EL0609
KYHA0918 541998.4 8479799.5 1117.3 HA 9 25/11/2021 EL0609
KYHA0919 542002.5 8479400.2 1118.4 HA 8 25/11/2021 EL0609
KYHA0920 542400.8 8479403.3 1119.8 HA 11 25/11/2021 EL0609
KYHA0921 538798.7 8479003.5 1087.3 HA 12 25/11/2021 EL0609
KYHA0922 539197.7 8479002.4 1089.8 HA 12 25/11/2021 EL0609
KYHA0923 541597.3 8479000.9 1117.1 HA 12 25/11/2021 EL0609
KYHA0924 540793.1 8479396.3 1108.6 HA 12 25/11/2021 EL0609
KYHA0925 542400.7 8479803.3 1124.1 HA 12 25/11/2021 EL0609
KYHA0926 542198.0 8480003.7 1122.1 HA 12 26/11/2021 EL0609
KYHA0927 542399.7 8480199.7 1124.9 HA 11 26/11/2021 EL0609
KYHA0928 542003.9 8480199.4 1114.5 HA 6 26/11/2021 EL0609
KYHA0929 542200.2 8480401.0 1117.0 HA 8 26/11/2021 EL0609
KYHA0930 541792.0 8480398.1 1107.6 HA 1 26/11/2021 EL0609
KYHA0931 542597.7 8480801.2 1117.4 HA 3 26/11/2021 EL0609
KYHA0932 542004.1 8480600.9 1109.3 HA 2 26/11/2021 EL0609
KYHA0933 542399.2 8480599.3 1117.9 HA 8 26/11/2021 EL0609
KYHA0934 542189.8 8480801.8 1110.3 HA 2 26/11/2021 EL0609
KYHA0935 541799.3 8480002.4 1109.3 HA 6 26/11/2021 EL0609
KYHA0936 542600.6 8480002.5 1127.0 HA 14 30/11/2021 EL0609
KYHA0937 542800.6 8480200.3 1130.1 HA 14 30/11/2021 EL0609
KYHA0938 543003.1 8480401.5 1132.5 HA 12 30/11/2021 EL0609
KYHA0939 543202.0 8480201.7 1135.1 HA 14 30/11/2021 EL0609
KYHA0940 544003.1 8480202.5 1145.1 HA 15 30/11/2021 EL0609
KYHA0941 543402.0 8480402.6 1138.3 HA 13 30/11/2021 EL0609
KYHA0942 543600.4 8480204.5 1139.7 HA 14 30/11/2021 EL0609
KYHA0943 544200.6 8480401.3 1146.5 HA 15 30/11/2021 EL0609
KYHA0944 542600.7 8480399.8 1126.6 HA 12 30/11/2021 EL0609
KYHA0945 543199.4 8479397.3 1131.2 HA 14.5 01/12/2021 EL0609
KYHA0946 543400.3 8479198.0 1137.6 HA 14 01/12/2021 EL0609
KYHA0947 543210.0 8478999.1 1133.6 HA 10.5 01/12/2021 EL0609
KYHA0948 543599.6 8478999.8 1143.9 HA 10 02/12/2021 EL0609
KYHA0949 543798.6 8479202.6 1145.3 HA 11 02/12/2021 EL0609
KYHA0950 543601.1 8479403.6 1140.9 HA 13 02/12/2021 EL0609
KYHA0951 544398.1 8480601.7 1145.2 HA 14 02/12/2021 EL0609
KYHA0952 544599.3 8480800.7 1141.6 HA 12 02/12/2021 EL0609
KYHA0953 544803.0 8480998.8 1137.4 HA 15 02/12/2021 EL0609
KYHA0954 542798.4 8480599.9 1126.7 HA 13 03/12/2021 EL0609
KYHA0955 543202.2 8480599.8 1133.9 HA 13 03/12/2021 EL0609
KYHA0956 543402.7 8480801.7 1135.3 HA 14 03/12/2021 EL0609
KYHA0957 543004.8 8480805.5 1125.5 HA 10 03/12/2021 EL0609
KYHA0958 543601.2 8480999.8 1137.0 HA 7 03/12/2021 EL0609
KYHA0959 543801.4 8480799.3 1142.8 HA 12 03/12/2021 EL0609
KYHA0960 543998.7 8480601.1 1146.1 HA 15 03/12/2021 EL0609
KYHA0961 543602.3 8480599.0 1141.0 HA 14 03/12/2021 EL0609
KYHA0962 543798.4 8480407.6 1144.4 HA 13 04/12/2021 EL0609
KYHA0963 544001.1 8481006.1 1144.5 HA 14 04/12/2021 EL0609
KYHA0964 544203.0 8480801.1 1146.8 HA 10 04/12/2021 EL0609
KYHA0965 544402.9 8481000.7 1143.7 HA 12 04/12/2021 EL0609
KYHA0966 544602.0 8481201.7 1139.7 HA 12 04/12/2021 EL0609
KYHA0967 544999.3 8481221.4 1133.2 HA 8 04/12/2021 EL0609
KYHA0968 544800.3 8481399.7 1134.8 HA 11 04/12/2021 EL0609
KYHA0969 544409.2 8481401.5 1140.2 HA 2 04/12/2021 EL0609
KYHA0970 544198.6 8481204.6 1143.9 HA 11 04/12/2021 EL0609
KYHA0971 543600.6 8478599.5 1142.6 HA 4 05/12/2021 EL0609
KYHA0972 543401.0 8478801.4 1138.9 HA 15 05/12/2021 EL0609
KYHA0973 543397.9 8478401.4 1135.2 HA 14 05/12/2021 EL0609
KYHA0974 543395.8 8477999.4 1129.9 HA 12 05/12/2021 EL0609
KYHA0975 543601.6 8477802.3 1125.5 HA 13 06/12/2021 EL0609
KYHA0976 543206.7 8477791.5 1123.3 HA 12 06/12/2021 EL0609
KYHA0977 542997.7 8477999.4 1122.3 HA 14 06/12/2021 EL0609
KYHA0978 543597.2 8478200.4 1135.7 HA 14 06/12/2021 EL0609
KYHA0979 543199.4 8478200.0 1129.3 HA 16 06/12/2021 EL0609
KYHA0980 543200.9 8478602.1 1132.7 HA 12 07/12/2021 EL0609
KYHA0981 543005.3 8478395.9 1125.8 HA 12 06/12/2021 EL0609
KYHA0982 543801.4 8481602.6 1142.4 HA 12 07/12/2021 EL0609
KYHA0983 543600.8 8481800.4 1139.1 HA 15 07/12/2021 EL0609
KYHA0984 539996.8 8479401.4 1098.7 HA 14 07/12/2021 EL0609
KYHA0985 543402.2 8481602.2 1134.5 HA 14 07/12/2021 EL0609
KYHA0986 543800.2 8482000.2 1141.5 HA 12 07/12/2021 EL0609
KYHA0987 543398.1 8482001.5 1134.2 HA 15 07/12/2021 EL0609
KYHA0988 543196.4 8482201.4 1127.5 HA 5 07/12/2021 EL0609
KYHA0989 541802.9 8480803.4 1104.7 HA 8 07/12/2021 EL0609
KYHA0990 543202.5 8481800.1 1131.3 HA 14 08/12/2021 EL0609
KYHA0991 543598.5 8482203.6 1134.9 HA 15 08/12/2021 EL0609
KYHA0992 543402.7 8482405.4 1128.4 HA 11 08/12/2021 EL0609
KYHA0993 543808.5 8482399.3 1133.5 HA 13 08/12/2021 EL0609
KYHA0994 543600.8 8482600.2 1127.6 HA 12 08/12/2021 EL0609
KYHA0995 543997.9 8482597.4 1130.3 HA 3 08/12/2021 EL0609
KYHA0996 543798.5 8482803.1 1122.2 HA 9 08/12/2021 EL0609
KYHA0997 544197.2 8483202.8 1123.5 HA 5 08/12/2021 EL0609
KYHA0998 544599.6 8483200.6 1131.8 HA 15 08/12/2021 EL0609
KYHA0999 544399.5 8483000.3 1130.7 HA 14 09/12/2021 EL0609
KYHA1000 544401.8 8483401.1 1128.6 HA 4 09/12/2021 EL0609
KYHA1001 544202.1 8483597.8 1124.9 HA 10 09/12/2021 EL0609
KYHA1002 544603.2 8483602.9 1130.5 HA 15 09/12/2021 EL0609
KYHA1003 545003.8 8483599.5 1132.4 HA 15 09/12/2021 EL0609
KYHA1004 544801.5 8483801.2 1130.9 HA 14 09/12/2021 EL0609
KYHA1005 544598.4 8484002.5 1129.0 HA 12 09/12/2021 EL0609
KYHA1006 545200.2 8483797.5 1130.9 HA 15 09/12/2021 EL0609
KYHA1007 545001.2 8484006.3 1129.7 HA 13 09/12/2021 EL0609
KYHA1008 544002.3 8483400.0 1117.9 HA 7 09/12/2021 EL0609
KYHA1009 544399.9 8483801.6 1128.1 HA 14 10/12/2021 EL0609
KYHA1010 544801.6 8483401.9 1132.1 HA 16 10/12/2021 EL0609
KYHA1011 544199.9 8482801.2 1129.4 HA 13 10/12/2021 EL0609
KYHA1012 543993.9 8483002.6 1120.0 HA 3 10/12/2021 EL0609
KYHA1013 541602.8 8481802.1 1113.5 HA 13 10/12/2021 EL0609
KYHA1014 541800.5 8482000.4 1115.8 HA 15 10/12/2021 EL0609
KYHA1015 542001.3 8482199.9 1117.2 HA 13 10/12/2021 EL0609
KYHA1016 543556.7 8483013.2 1116.1 HA 6 10/12/2021 EL0609
KYHA1017 543801.2 8483203.6 1114.9 HA 4 10/12/2021 EL0609
KYHA1018 541999.8 8482597.6 1113.3 HA 12 11/12/2021 EL0609
KYHA1019 541799.2 8482404.1 1114.8 HA 14 11/12/2021 EL0609
KYHA1020 541597.1 8482205.0 1114.6 HA 15 11/12/2021 EL0609
KYHA1021 541400.1 8481999.9 1113.0 HA 13 11/12/2021 EL0609
KYHA1022 541197.4 8481803.0 1111.1 HA 12 11/12/2021 EL0609
KYHA1023 541396.9 8481601.7 1110.6 HA 12 11/12/2021 EL0609
KYHA1024 542199.4 8482402.7 1117.0 HA 12 11/12/2021 EL0609
KYHA1025 541602.0 8482601.8 1111.5 HA 15 13/12/2021 EL0609
KYHA1026 541402.1 8482400.0 1112.0 HA 15 13/12/2021 EL0609
KYHA1027 541203.2 8482200.4 1110.3 HA 6.5 13/12/2021 EL0609
KYHA1028 541003.2 8481601.0 1109.0 HA 14 13/12/2021 EL0609
KYHA1029 540802.4 8481400.7 1106.4 HA 12 13/12/2021 EL0609
KYHA1030 541201.0 8481401.4 1107.7 HA 13 13/12/2021 EL0609
KYHA1031 540998.4 8481209.6 1104.5 HA 10 13/12/2021 EL0609
KYHA1032 537403.1 8476804.0 1093.9 HA 12 14/12/2021 EL0609
KYHA1033 536999.1 8476800.4 1094.9 HA 14 14/12/2021 EL0492
KYHA1034 537200.6 8476999.2 1093.5 HA 16 14/12/2021 EL0609
KYHA1035 537399.2 8477200.3 1091.0 HA 14 14/12/2021 EL0492
KYHA1036 537000.0 8477204.5 1091.1 HA 13 14/12/2021 EL0492
KYHA1037 537200.6 8477397.5 1090.3 HA 14 14/12/2021 EL0492
KYHA1038 537001.5 8477603.4 1088.1 HA 12 14/12/2021 EL0492
KYHA1039 537405.8 8477595.8 1087.3 HA 10 14/12/2021 EL0609
KYHA1040 537599.0 8477802.7 1077.9 HA 6 14/12/2021 EL0492
KYHA1041 537793.2 8478002.7 1070.8 HA 2 14/12/2021 EL0492
KYHA1042 537799.4 8477602.5 1079.8 HA 7 14/12/2021 EL0609
KYHA1043 537999.7 8477798.9 1071.7 HA 6 15/12/2021 EL0609
KYHA1044 537594.1 8477396.0 1087.5 HA 12 15/12/2021 EL0609
KYHA1045 538000.3 8477401.8 1080.2 HA 2 15/12/2021 EL0609
KYHA1046 537202.0 8477799.0 1085.8 HA 14 15/12/2021 EL0492
KYHA1047 537400.9 8477999.7 1075.9 HA 5 15/12/2021 EL0492
KYHA1048 538202.5 8477999.0 1068.3 HA 8 15/12/2021 EL0609
KYHA1049 540600.2 8479800.5 1103.6 HA 12 19/01/2022 EL0609
KYHA1050 542202.2 8479803.0 1121.9 HA 10 19/01/2022 EL0609
KYHA1051 542199.9 8480600.2 1113.7 HA 8 19/01/2022 EL0609
KYHA1052 543400.0 8480600.5 1137.4 HA 11 20/01/2022 EL0609
KYHA1053 543799.9 8480200.5 1142.9 HA 14 20/01/2022 EL0609
KYHA1054 539800.1 8479400.6 1097.8 HA 14 20/01/2022 EL0609
KYHA1055 543800.0 8479000.4 1146.8 HA 10 21/01/2022 EL0609
KYHA1056 543398.0 8478599.4 1137.4 HA 11 21/01/2022 EL0609
KYHA1057 541007.2 8481390.6 1106.9 HA 9 21/01/2022 EL0609
KYHA1058 541395.1 8481801.5 1112.1 HA 10 21/01/2022 EL0609
KYHA1059 544600.0 8482600.3 1135.7 HA 14 24/01/2022 EL0609
KYHA1060 544600.0 8483000.2 1133.3 HA 12 24/01/2022 EL0609
KYHA1061 544599.9 8483800.5 1129.8 HA 11 24/01/2022 EL0609
KYHA1062 544600.0 8481001.0 1141.2 HA 12 25/01/2022 EL0609
KYHA1063 537799.8 8477800.3 1075.4 HA 8 25/01/2022 EL0609
KYHA1064 537000.0 8477400.5 1089.5 HA 11 26/01/2022 EL0492
KYHA1065 539798.0 8472799.4 1136.9 HA 14 26/01/2022 EL0609
KYHA1066 538998.0 8472802.8 1126.5 HA 12 27/01/2022 EL0609
KYHA1068 550438.0 8479180.0 1114.1 HA 8 12/04/2022 EL0609
KYHA1079 550833.6 8480356.2 1107.0 HA 6 14/04/2022 EL0609
KYHA1080 550806.6 8479996.4 1113.8 HA 10 14/04/2022 EL0609
KYHA1081 550799.4 8479599.8 1116.0 HA 6 14/04/2022 EL0609
KYHA1082 550808.6 8479196.7 1118.7 HA 5 14/04/2022 EL0609
KYHA1083 550805.4 8478800.9 1125.2 HA 3 14/04/2022 EL0609
KYHA1114 549200.4 8476799.3 1136.5 HA 9 20/04/2022 EL0609
KYHA1115 548399.8 8478004.8 1134.3 HA 8 22/04/2022 EL0609
KYHA1126 542400.4 8484801.3 1107.6 HA 13 22/04/2022 EL0609
KYHA1136 543000.2 8484596.8 1113.9 HA 12 25/04/2022 EL0609
KYHA1138 542599.4 8484601.1 1112.1 HA 13 26/04/2022 EL0609
KYHA1141 542599.6 8484205.8 1114.4 HA 12 26/04/2022 EL0609
KYHA1143 542999.2 8484204.4 1116.6 HA 12 26/04/2022 EL0609
KYHA1145 542000.1 8483604.7 1098.9 HA 8 27/04/2022 EL0609
KYHA1151 547202.5 8473202.6 1160.4 HA 13 27/04/2022 EL0582
KYHA1173 544800.0 8472000.0 1133.0 HA 12 03/05/2022 EL0582
KYHA1206 542797.5 8465200.6 1145.0 HA 9 10/05/2022 EL0582
KYHA1215 537601.5 8470401.2 1106.7 HA 4 11/05/2022 EL0609
KYHA1227 539196.6 8470002.4 1136.1 HA 12 13/05/2022 EL0609
KYHA1228 547202.7 8479201.6 1150.0 HA 12 13/05/2022 EL0609
KYHA1229 545999.5 8478802.1 1147.1 HA 12 13/05/2022 EL0609
KYHA1230 545202.3 8478001.5 1136.6 HA 13 13/05/2022 EL0609
KYHA1231 543798.7 8479203.1 1145.3 HA 11 14/05/2022 EL0609
KYHA1232 540797.8 8478800.2 1108.2 HA 16 14/05/2022 EL0609
KYHA1233 541202.7 8479802.8 1107.3 HA 10 14/05/2022 EL0609
KYHA1234 542200.7 8480401.6 1117.0 HA 8 14/05/2022 EL0609
KYHA1235 545616.8 8480378.4 1129.9 HA 6 14/05/2022 EL0609
KYHA1236 540802.6 8481400.2 1106.4 HA 12 16/05/2022 EL0609
KYHA1237 541802.9 8480803.7 1104.7 HA 8 16/05/2022 EL0609
KYHA1238 544399.8 8483801.9 1128.1 HA 14 17/05/2022 EL0609
KYHA1239 544800.4 8484401.2 1123.9 HA 12 17/05/2022 EL0609
KYHA1240 544800.1 8481400.0 1134.8 HA 11 17/05/2022 EL0609
KYHA1241 546795.7 8484005.9 1114.8 HA 11 17/05/2022 EL0609
KYHA1242 548400.3 8485999.0 1101.1 HA 11 17/05/2022 EL0609
KYHA1243 537598.7 8472000.6 1123.0 HA 10 18/05/2022 EL0609
KYHA1244 540398.6 8473200.9 1121.5 HA 8 18/05/2022 EL0609
KYHA1245 537599.6 8480402.2 1072.6 HA 7 18/05/2022 EL0492
KYHA1246 543597.3 8473199.3 1119.4 HA 12 18/05/2022 EL0609
KYHA1247 536405.4 8475603.5 1095.6 HA 6 18/05/2022 EL0609
KYHA1248 543188.2 8473995.1 1107.7 HA 8 19/05/2022 EL0609
KYHA1249 546800.3 8476401.0 1146.1 HA 11 19/05/2022 EL0609
KYHA1252 544404.8 8472006.1 1129.6 HA 11 19/05/2022 EL0582
KYHA1253 547200.6 8472400.5 1163.7 HA 12 20/05/2022 EL0582
KYHA1256 542800.1 8470398.8 1118.0 HA 11 20/05/2022 EL0582
KYHA1257 544796.4 8467603.6 1140.5 HA 9 20/05/2022 EL0582
KYHA1258 545201.2 8467200.6 1139.8 HA 7 20/05/2022 EL0582
KYHA1260 542000.3 8468800.3 1136.0 HA 6 21/05/2022 EL0582
KYHA1261 544000.3 8468409.6 1137.7 HA 10 21/05/2022 EL0582
KYHA1263 546801.0 8462199.3 1182.9 HA 6 22/05/2022 EL0582
KYHA1265 546001.0 8465997.1 1151.9 HA 3 22/05/2022 EL0582
KYHA1266 544799.3 8464400.0 1154.4 HA 8 22/05/2022 EL0582
KYHA1267 543602.7 8472001.7 1122.6 HA 12 02/11/2022 EL0609
KYHA1268 543204.4 8470399.3 1116.1 HA 9 02/11/2022 EL0582
KYHA1269 543601.7 8472001.8 1122.6 HA 12 04/11/2022 EL0609
KYHA1270 543197.4 8470399.3 1116.4 HA 9 04/11/2022 EL0582
KYHA1271 543602.7 8472001.7 1122.6 HA 11 23/11/2022 EL0609
KYHA1328 541200.5 8467602.6 1154.1 HA 14 15/11/2023 EL0582
KYHA1329 540406.8 8467602.0 1152.3 HA 14 15/11/2023 EL0582
KYHA1330 540000.6 8467602.4 1150.8 HA 14 15/11/2023 EL0582
KYHA1331 539598.7 8467598.8 1146.9 HA 14 15/11/2023 EL0609
KYHA1332 539200.6 8467600.1 1143.1 HA 14 15/11/2023 EL0609
KYHA1333 545999.8 8469985.6 1126.4 HA 4 17/11/2023 EL0582
KYHA1334 545999.4 8470399.9 1132.5 HA 3 17/11/2023 EL0582
KYHA1335 545998.5 8470798.8 1139.9 HA 12 17/11/2023 EL0582
KYHA1336 545997.0 8469601.0 1135.8 HA 11 17/11/2023 EL0582
KYHA1337 546000.0 8471199.9 1133.1 HA 4 17/11/2023 EL0582
KYHA1338 545998.9 8472020.7 1146.1 HA 11 18/11/2023 EL0582
KYHA1339 546033.4 8471616.1 1133.7 HA 3 19/11/2023 EL0582
KYHA1340 545997.3 8472399.5 1152.8 HA 15 19/11/2023 EL0582
KYHA1341 545600.7 8472401.2 1146.0 HA 10 20/11/2023 EL0582
KYHA1342 546402.1 8472402.5 1153.6 HA 5 20/11/2023 EL0582
KYHA1343 546399.1 8473202.4 1150.2 HA 10 20/11/2023 EL0582
KYHA1344 546000.4 8473203.4 1148.1 HA 14 20/11/2023 EL0582
KYHA1345 545600.5 8473199.3 1143.1 HA 6 21/11/2023 EL0582
KYHA1346 545201.8 8473202.2 1139.7 HA 10 21/11/2023 EL0582
KYHA1347 545209.2 8472418.6 1134.3 HA 3 21/11/2023 EL0582
KYHA1348 546000.1 8473602.7 1137.3 HA 3 21/11/2023 EL0582
KYHA1349 545997.4 8473998.4 1127.6 HA 6 22/11/2023 EL0582
KYHA1350 539589.6 8469201.2 1150.2 HA 14 28/11/2023 EL0609
KYHA1351 540001.6 8469199.1 1152.6 HA 14 28/11/2023 EL0582
KYHA1352 540802.5 8469200.1 1147.5 HA 11 28/11/2023 EL0582
KYHA1353 534800.1 8480798.9 1065.5 HA 6 29/11/2023 EL0492
KYHA1354 534799.2 8480396.7 1061.7 HA 11 29/11/2023 EL0492
KYHA1355 534801.0 8479997.7 1050.2 HA 6 29/11/2023 EL0492
KYHA1356 534797.4 8479600.9 1053.6 HA 4 29/11/2023 EL0492
KYHA1357 534800.8 8479201.8 1068.7 HA 3 29/11/2023 EL0492
KYHA1358 536001.7 8480798.3 1071.9 HA 8 29/11/2023 EL0492
KYHA1359 535995.5 8480399.7 1056.8 HA 4 30/11/2023 EL0492
KYHA1360 536000.1 8479999.2 1056.3 HA 12 30/11/2023 EL0492
KYHA1361 536005.0 8479595.5 1064.8 HA 14 30/11/2023 EL0492
KYHA1362 536002.6 8479202.2 1066.6 HA 13 30/11/2023 EL0492
KYHA1363 539204.0 8466000.4 1134.4 HA 6 02/12/2023 EL0609
KYHA1364 539601.9 8466000.0 1141.0 HA 2 02/12/2023 EL0609
KYHA1365 539999.1 8466000.5 1145.3 HA 12 02/12/2023 EL0609
KYHA1366 540399.4 8465998.7 1154.7 HA 15 02/12/2023 EL0582
KYHA1367 541195.9 8465996.3 1157.8 HA 14 03/12/2023 EL0582
KYHA1368 540401.1 8465600.0 1151.6 HA 15 03/12/2023 EL0582
KYHA1369 540800.8 8465601.2 1157.4 HA 14 04/12/2023 EL0582
KYHA1370 540402.0 8465201.3 1144.6 HA 15 04/12/2023 EL0582
KYHA1371 540803.2 8465201.1 1150.7 HA 14 05/12/2023 EL0582
KYHA1372 541198.9 8465207.4 1156.4 HA 14 05/12/2023 EL0582
KYHA1373 538805.0 8466000.7 1129.5 HA 6 06/12/2023 EL0609
KYHA1374 538399.8 8465996.1 1125.9 HA 7 06/12/2023 EL0609
KYHA1375 538001.5 8465997.7 1120.7 HA 3 06/12/2023 EL0609
KYHA1376 537601.4 8466012.8 1117.7 HA 6 06/12/2023 EL0710
KYHA1377 537199.4 8465995.7 1117.4 HA 4 07/12/2023 EL0710
KYHA1378 536798.1 8465999.8 1120.8 HA 9 07/12/2023 EL0710
KYHA1379 536399.4 8465998.2 1122.9 HA 13 07/12/2023 EL0710
KYHA1380 535993.2 8466003.2 1122.4 HA 13 07/12/2023 EL0710
KYHA1381 535606.4 8465996.1 1119.5 HA 9 08/12/2023 EL0710
KYHA1382 535205.6 8466005.8 1114.4 HA 10 08/12/2023 EL0710
KYHA1383 534791.6 8467552.0 1102.5 HA 12 09/12/2023 EL0710
KYHA1384 535196.2 8467605.3 1102.8 HA 10 09/12/2023 EL0710
KYHA1385 535600.5 8467602.5 1101.8 HA 2 09/12/2023 EL0710
KYHA1386 536001.6 8467601.3 1101.1 HA 5 09/12/2023 EL0710
KYHA1387 537999.2 8467600.0 1128.5 HA 11 07/02/2024 EL0710
KYHA1388 537600.4 8467600.7 1124.1 HA 3 07/02/2024 EL0710
KYHA1389 537200.2 8467599.8 1118.8 HA 10 08/02/2024 EL0710
KYHA1390 536868.0 8467600.7 1114.3 HA 7 08/02/2024 EL0710
KYHA1391 536398.6 8467598.3 1108.0 HA 4 08/02/2024 EL0710
KYHA1392 538391.7 8467604.4 1133.1 HA 12 08/02/2024 EL0609
KYHA1393 538797.3 8467600.1 1137.5 HA 8 08/02/2024 EL0609
KYHA1394 536001.0 8469198.1 1119.5 HA 11 09/02/2024 EL0609
KYHA1395 536404.7 8469202.3 1119.4 HA 10 09/02/2024 EL0609
KYHA1396 536800.6 8469201.8 1120.2 HA 4 09/02/2024 EL0609
KYHA1397 537200.2 8469204.0 1123.5 HA 11 09/02/2024 EL0609
KYHA1398 534802.6 8469202.5 1109.3 HA 12 12/02/2024 EL0609
KYHA1399 535203.2 8469202.0 1114.3 HA 12 12/02/2024 EL0609
KYHA1400 535603.3 8469199.2 1119.1 HA 12 12/02/2024 EL0609
KYHA1410 544923.5 8480512.0 1133.4 HA 6 15/04/2025 EL0609
KYHA1411 544156.2 8481165.5 1144.4 HA 6 08/04/2025 EL0609
KYHA1412 544534.1 8481204.5 1140.6 HA 6 08/04/2025 EL0609
KYHA1413 544955.7 8481285.6 1133.4 HA 6 08/04/2025 EL0609
KYHA1414 545005.1 8480806.3 1132.1 HA 6 17/04/2025 EL0609
KYHA1415 544236.0 8480365.5 1146.5 HA 6 08/04/2025 EL0609
KYHA1416 544738.9 8480144.9 1139.5 HA 6 08/04/2025 EL0609
KYHA1417 544624.9 8479818.3 1142.5 HA 6 08/04/2025 EL0609
KYHA1418 544481.1 8480121.0 1143.8 HA 6 08/04/2025 EL0609
KYHA1419 544235.5 8479646.0 1146.2 HA 6 08/04/2025 EL0609
KYHA1420 544892.2 8471973.4 1133.9 HA 6 11/04/2025 EL0582
KYHA1421 544783.2 8471486.4 1126.5 HA 6 11/04/2025 EL0582
KYHA1422 544101.6 8471543.9 1119.9 HA 6 11/04/2025 EL0582
KYHA1423 543900.0 8471900.6 1124.7 HA 6 11/04/2025 EL0582
KYHA1424 544281.3 8472295.7 1127.1 HA 6 12/04/2025 EL0582
KYHA1425 543394.5 8472403.8 1115.6 HA 6 12/04/2025 EL0609
KYHA1426 543088.2 8472177.9 1116.2 HA 6 12/04/2025 EL0609
KYHA1427 543094.6 8471705.0 1115.0 HA 6 12/04/2025 EL0582
KYHA1428 543191.0 8471031.3 1107.0 HA 6 12/04/2025 EL0582
KYHA1429 542900.4 8470104.3 1124.7 HA 6 16/04/2025 EL0582
KYHA1432 543679.5 8471901.3 1123.7 HA 17 14/06/2025 EL0582
KYHA1433 543659.4 8471901.1 1123.7 HA 17 14/06/2025 EL0582
KYHA1434 543639.4 8471901.0 1123.4 HA 15 14/06/2025 EL0582
KYHA1435 543619.3 8471900.8 1123.4 HA 16 14/06/2025 EL0582
KYHA1436 543599.5 8471900.6 1123.4 HA 15 14/06/2025 EL0582
KYHA1437 543579.5 8471900.6 1123.2 HA 16 17/06/2025 EL0582
KYHA1438 543559.7 8471900.4 1123.2 HA 16 17/06/2025 EL0582
KYHA1439 543539.9 8471900.0 1123.1 HA 10 17/06/2025 EL0582
KYHA1440 543520.1 8471900.1 1123.2 HA 16 17/06/2025 EL0582
KYHA1466 543600.0 8471979.9 1122.7 HA 14 27/06/2025 EL0582
KYHA1467 543599.9 8471960.1 1122.9 HA 13 27/06/2025 EL0582
KYHA1468 543600.0 8471940.1 1123.1 HA 14 27/06/2025 EL0582
KYHA1469 543598.3 8471920.0 1123.4 HA 15 27/06/2025 EL0582
KYHA1470 543600.1 8471879.9 1123.3 HA 15 27/06/2025 EL0582
KYHA1471 543599.9 8471860.0 1123.4 HA 12 27/06/2025 EL0582
KYHA1472 543599.9 8471840.0 1123.4 HA 13 01/07/2025 EL0582
KYHA1473 543599.7 8471820.5 1123.4 HA 13 01/07/2025 EL0582
KYHA1474 546401.14 8467598.9 1167.897 HA 19 30/06/2025 EL0582/20R2
KYHA1475 546300.41 8467504.4 1166.625 HA 21 01/07/2025 EL0582/20R2
KYHA1476 545500.07 8465500.1 1164.898 HA 17 03/07/2025 EL0582/20R2
KYHA1477 545600.25 8465399.6 1166.382 HA 15 04/07/2025 EL0582/20R2
KYHA1478 544300.57 8471700.5 1125.529 HA 8 06/08/2025 EL0582/20R2
KYHA1479 544298.38 8471701.5 1125.492 HA 8 06/08/2025 EL0582/20R2
KYHA1480 544300.89 8471701.5 1125.557 HA 8 06/08/2025 EL0582/20R2
KYHA1481 544701.84 8472098.2 1132.547 HA 8 08/08/2025 EL0582/20R2
KYHA1482 544700.23 8472097.4 1132.53 HA 8 08/08/2025 EL0582/20R2
KYHA1483 544699.29 8472098.7 1132.533 HA 8 08/08/2025 EL0582/20R2
KYHA1484 543300.28 8472101.7 1120.736 HA 8 08/08/2025 EL0609
KYHA1485 543299.96 8472102.9 1120.736 HA 8 08/08/2025 EL0609
KYHA1486 543298.72 8472102.6 1120.736 HA 8 08/08/2025 EL0609
KYHA1487 543499.98 8471502.3 1119.664 HA 8 09/08/2025 EL0582/20R2
KYHA1488 543499.67 8471503.6 1119.688 HA 8 09/08/2025 EL0582/20R2
KYHA1489 543497.69 8471503.3 1119.68 HA 8 09/08/2025 EL0582/20R2
KYHA1490 543199.94 8470201.5 1120.58 HA 8 09/08/2025 EL0582/20R2
KYHA1491 543201.62 8470201.8 1120.554 HA 8 09/08/2025 EL0582/20R2
KYHA1492 543201.54 8470200.4 1120.587 HA 6 09/08/2025 EL0582/20R2
KYHA1493 543099.78 8469902 1125.999 HA 8 10/08/2025 EL0582/20R2
KYHA1494 543100.93 8469902.8 1125.966 HA 8 10/08/2025 EL0582/20R2
KYHA1495 543101.4 8469901.7 1125.988 HA 8 14/08/2025 EL0582/20R2
KYHA1496 543398.71 8469601.6 1121.35 HA 7 14/08/2025 EL0582/20R2
KYHA1497 543400.17 8469602.5 1121.281 HA 7 14/08/2025 EL0582/20R2
KYHA1498 543400.91 8469601.4 1121.26 HA 7 18/08/2025 EL0582/20R2
KYHA1499 543901.38 8468101.6 1139.339 HA 8 18/08/2025 EL0582/20R2
KYHA1500 543900.65 8468103.1 1139.29 HA 8 18/08/2025 EL0582/20R2
KYHA1501 543899.41 8468102.3 1139.302 HA 8 18/08/2025 EL0582/20R2
KYHA1502 544499.11 8468697.5 1137.42 HA 8 18/08/2025 EL0582/20R2
KYHA1503 544500.52 8468697.8 1137.408 HA 8 18/08/2025 EL0582/20R2
KYHA1504 544498.54 8468698.7 1137.413 HA 8 18/08/2025 EL0582/20R2
KYHA1505 542912.55 8469607.5 1130.369 HA 6 25/08/2025 EL0582/20R2
KYHA1506 542803.1 8469505.3 1131.916 HA 6 25/08/2025 EL0582/20R2
KYHA1507 542603.19 8469605 1131.927 HA 6 25/08/2025 EL0582/20R2
KYHA1508 543001.79 8469406.6 1130.497 HA 6 25/08/2025 EL0582/20R2
KYHA1509 542803.47 8469305.4 1132.903 HA 6 26/08/2025 EL0582/20R2
KYHA1510 543003.58 8469205.5 1130.606 HA 6 26/08/2025 EL0582/20R2
KYHA1511 543002.58 8469004.3 1130.298 HA 6 26/08/2025 EL0582/20R2
KYHA1512 542803.22 8469105.4 1133.517 HA 6 26/08/2025 EL0582/20R2
KYHA1513 542802.36 8468905.1 1133.739 HA 6 26/08/2025 EL0582/20R2
KYHA1514 542603.24 8469005 1136.307 HA 6 26/08/2025 EL0582/20R2
KYHA1515 542603.18 8469205.1 1135.207 HA 6 26/08/2025 EL0582/20R2
KYHA1516 542607.65 8469405.1 1133.76 HA 6 26/08/2025 EL0582/20R2
KYHA1517 542403.19 8468905.4 1138.038 HA 6 26/08/2025 EL0582/20R2
KYHA1518 542403.19 8469105.4 1136.46 HA 6 26/08/2025 EL0582/20R2
KYHA1519 542403.66 8469305.1 1134.455 HA 6 26/08/2025 EL0582/20R2
KYHA1520 542403.26 8469505.4 1132.165 HA 5.52 26/08/2025 EL0582/20R2
KYHA1521 542527.99 8478500 1109.068 HA 5 02/09/2025 EL0609
KYHA1522 542594.14 8478550 1111.2 HA 5 02/09/2025 EL0609
KYHA1523 542670.04 8478600 1113.631 HA 5 02/09/2025 EL0609
KYHA1524 542509.77 8478400.2 1109.287 HA 5 02/09/2025 EL0609
KYHA1525 542598.13 8478450.1 1111.283 HA 5 02/09/2025 EL0609
KYHA1526 542669.99 8478500 1113.763 HA 5 02/09/2025 EL0609
KYHA1527 542680.02 8478400 1113.334 HA 5 02/09/2025 EL0609
KYHA1528 542602.16 8478350.5 1111.719 HA 5 02/09/2025 EL0609
KYHA1529 542529.73 8478300 1110.557 HA 1 02/09/2025 EL0609
KYHA1530 542680.02 8478300 1113.756 HA 4 02/09/2025 EL0609
KYHA1531 542606.65 8478250 1112.171 HA 0.74 02/09/2025 EL0609
KYHA1532 542530.03 8478200 1111.417 HA 5 02/09/2025 EL0609
KYHA1533 542700 8478200 1114.275 HA 5 02/09/2025 EL0609
KYHA1534 542610.37 8478153.3 1112.531 HA 5 02/09/2025 EL0609
KYHA1535 542541.08 8478100 1111.366 HA 4 02/09/2025 EL0609
KYHA1536 542699.95 8478100 1113.186 HA 5 03/09/2025 EL0609
KYHA1537 542614.98 8478050 1111.492 HA 0.78 03/09/2025 EL0609
KYHA1538 542539.98 8478000 1110.342 HA 5 03/09/2025 EL0609
KYHA1539 542709.98 8478000 1112.457 HA 3 03/09/2025 EL0609
KYHA1540 542619.2 8477950 1110.35 HA 5 03/09/2025 EL0609
KYHA1541 542550.03 8477900 1108.477 HA 2 03/09/2025 EL0609
KYHA1542 542689.99 8477800 1109.41 HA 5 03/09/2025 EL0609
KYHA1543 542622.59 8477850.5 1109.085 HA 6 03/09/2025 EL0609
KYHA1544 542564.9 8477800.2 1107.191 HA 0.26 03/09/2025 EL0609
KYHA1545 542627.47 8477750 1107.569 HA 5 03/09/2025 EL0609
KYHA1546 542710.03 8477900 1111.452 HA 4.5 03/09/2025 EL0609
KYHA1547 542990.74 8477995.1 1122.071 HA 6 03/09/2025 EL0609
KYHA1548 543040.33 8478041.7 1124.446 HA 5 03/09/2025 EL0609
KYHA1549 542940.39 8478046.5 1120.259 HA 5 03/09/2025 EL0609
KYHA1550 542999.69 8478093.7 1123.077 HA 6 03/09/2025 EL0609
KYHA1551 543050.32 8478145 1125.058 HA 6.23 04/09/2025 EL0609
KYHA1552 543058.63 8478245 1126.716 HA 6 04/09/2025 EL0609
KYHA1553 543008.67 8478195 1124.274 HA 6 04/09/2025 EL0609
KYHA1554 542950.33 8478145 1121.606 HA 5 04/09/2025 EL0609
KYHA1555 542958.66 8478245.1 1122.749 HA 5 04/09/2025 EL0609
KYHA1556 543016.98 8478295 1125.448 HA 4 04/09/2025 EL0609
KYHA1557 544118.51 8479399.1 1146.412 HA 5 04/09/2025 EL0609
KYHA1558 544225.12 8479292.6 1145.898 HA 6 04/09/2025 EL0609
KYHA1559 544003.77 8479300 1146.633 HA 4.5 04/09/2025 EL0609
KYHA1560 544076.1 8479200.2 1146.643 HA 5 04/09/2025 EL0609
KYHA1561 544177.29 8479100 1145.733 HA 6 04/09/2025 EL0609
KYHA1562 544277.25 8479000 1144.087 HA 5.12 04/09/2025 EL0609
KYHA1563 543977.35 8479099.9 1146.791 HA 5 05/09/2025 EL0609
KYHA1564 544029.65 8479000 1146.369 HA 4 05/09/2025 EL0609
KYHA1565 544129.68 8478900 1144.525 HA 4.65 05/09/2025 EL0609
KYHA1566 544229.65 8478800 1142.121 HA 6 05/09/2025 EL0609
KYHA1567 543877.29 8479000 1146.791 HA 5 05/09/2025 EL0609
KYHA1568 543929.13 8478900.8 1146.899 HA 4.18 05/09/2025 EL0609
KYHA1569 543982.01 8478800 1145.133 HA 6 05/09/2025 EL0609
KYHA1570 544082.01 8478700 1142.608 HA 6 05/09/2025 EL0609
KYHA1571 544149.96 8478630 1140.244 HA 6 05/09/2025 EL0609
KYHA1572 543777.33 8478900 1148.096 HA 5 05/09/2025 EL0609
KYHA1573 543829.68 8478800 1146.717 HA 5 05/09/2025 EL0609
KYHA1574 543882.01 8478700 1144.815 HA 6 05/09/2025 EL0609
KYHA1575 543934.21 8478600.1 1142.414 HA 6 05/09/2025 EL0609
KYHA1576 544034.25 8478499.9 1138.999 HA 6 05/09/2025 EL0609
KYHA1577 543781.96 8478592.9 1143.499 HA 6 05/09/2025 EL0609
KYHA1578 543834.29 8478500 1141.175 HA 6 05/09/2025 EL0609
KYHA1579 543886.66 8478400 1138.585 HA 6 05/09/2025 EL0609
KYHA1580 543986.7 8478300 1136.085 HA 5 05/09/2025 EL0609
KYHA1581 543734.32 8478400 1139.542 HA 6 05/09/2025 EL0609
KYHA1582 543786.67 8478300 1137.465 HA 4 05/09/2025 EL0609
KYHA1583 543838.98 8478200 1135.427 HA 5 05/09/2025 EL0609
KYHA1584 542403.55 8469705.2 1130.498 HA 6 06/09/2025 EL0582/20R2
KYHA1585 542603.24 8469805 1129.493 HA 5 06/09/2025 EL0582/20R2
KYHA1586 542802.13 8469702.9 1130.396 HA 5 06/09/2025 EL0582/20R2
KYHA1587 542471 8469910 1127.308 HA 5 06/09/2025 EL0582/20R2
KYHA1588 542703.93 8469903 1128.437 HA 5 06/09/2025 EL0582/20R2
KYHA1589 542699.95 8470149.9 1124.794 HA 3.4 06/09/2025 EL0582/20R2
KYHA1590 542849.96 8470140 1124.81 HA 5 06/09/2025 EL0582/20R2
KYHA1591 542948.91 8470312.2 1121.394 HA 5 06/09/2025 EL0582/20R2
KYHA1592 542940.05 8470466 1115.774 HA 5 06/09/2025 EL0582/20R2
KYHA1593 542820.06 8470308 1121.294 HA 6 08/09/2025 EL0582/20R2
KYHA1594 542799.93 8470450 1115.907 HA 5 08/09/2025 EL0582/20R2
KYHA1595 542945.05 8470590 1111.63 HA 6 08/09/2025 EL0582/20R2
KYHA1596 543060 8470624.1 1110.781 HA 5 08/09/2025 EL0582/20R2
KYHA1597 543053.96 8470489 1114.48 HA 7 08/09/2025 EL0582/20R2
KYHA1598 543749.71 8468204.2 1134.379 HA 6 13/10/2025 EL0582/20R2
KYHA1599 543652.3 8468098.2 1132.636 HA 5 17/10/2025 EL0582/20R2
KYHA1600 543649.46 8468497.3 1127.116 HA 5 17/10/2025 EL0582/20R2
KYHA1601 543851.31 8468098.4 1138.45 HA 5 17/10/2025 EL0582/20R2
KYHA1602 543655.33 8468297.8 1129.153 HA 5 17/10/2025 EL0582/20R2
KYHA1603 543552.74 8468201.1 1127.856 HA 5 17/10/2025 EL0582/20R2
KYHA1604 543749.13 8468002.5 1136.866 HA 5 17/10/2025 EL0582/20R2
KYHA1605 543850.4 8467900 1140.393 HA 5 17/10/2025 EL0582/20R2
KYHA1606 543838.84 8467700.1 1141.488 HA 4 17/10/2025 EL0582/20R2
KYHA1607 543835.07 8467501 1142.485 HA 5 17/10/2025 EL0582/20R2
KYHA1608 543850.83 8468298.3 1135.363 HA 6 13/10/2025 EL0582/20R2
KYHA1609 543750.19 8468398.5 1130.075 HA 6 13/10/2025 EL0582/20R2
KYHA1610 543548.4 8468000 1130.335 HA 6 21/10/2025 EL0582/20R2
KYHA1611 543649.1 8467899 1135.524 HA 6 21/10/2025 EL0582/20R2
KYHA1612 543550.3 8467800 1132.818 HA 6 21/10/2025 EL0582/20R2
KYHA1613 543472.8 8467700 1131.015 HA 6 21/10/2025 EL0582/20R2
KYHA1614 543749.3 8467801 1139.679 HA 6 21/10/2025 EL0582/20R2
KYHA1615 543648 8467701 1137.204 HA 6 21/10/2025 EL0582/20R2
KYHA1616 543547.4 8467601 1134.472 HA 6 21/10/2025 EL0582/20R2
KYHA1617 543469 8467502 1132.958 HA 6 21/10/2025 EL0582/20R2
KYHA1618 543750.2 8467602 1140.351 HA 5 21/10/2025 EL0582/20R2
KYHA1619 543649.47 8467502.1 1138.811 HA 1.2 21/10/2025 EL0582/20R2
KYHA1620 543550.2 8467399.6 1137.437 HA 5 22/10/2025 EL0582/20R2
KYHA1621 543470.82 8467299.6 1135.604 HA 4.7 22/10/2025 EL0582/20R2
KYHA1622 543551.46 8467200.3 1140.004 HA 1 22/10/2025 EL0582/20R2
KYHA1623 543649.49 8467299.1 1140.734 HA 4.2 22/10/2025 EL0582/20R2
KYHA1624 543750.16 8467399.2 1141.811 HA 1.7 22/10/2025 EL0582/20R2
KYHA1625 543750.81 8467249.5 1143.11 HA 4 22/10/2025 EL0582/20R2
KYHA1626 544516.9 8468150 1141.491 HA 6 22/10/2025 EL0582/20R2
KYHA1627 544617 8468064 1141.174 HA 5 22/10/2025 EL0582/20R2
KYHA1628 544716.1 8468152 1138.698 HA 3.6 22/10/2025 EL0582/20R2
KYHA1629 544818.1 8468078 1135.32 HA 2 22/10/2025 EL0582/20R2
KYHA1630 544618.5 8468251 1139.474 HA 6 22/10/2025 EL0582/20R2
KYHA1631 544517.5 8468350 1140.11 HA 5.54 23/10/2025 EL0582/20R2
KYHA1632 544617.4 8468448 1138.328 HA 4.75 23/10/2025 EL0582/20R2
KYHA1633 544715.7 8468348 1137.355 HA 6 23/10/2025 EL0582/20R2
KYHA1634 544816.1 8468250 1134.646 HA 2.62 23/10/2025 EL0582/20R2
KYHA1635 544817.66 8468450.1 1132.741 HA 4.73 23/10/2025 EL0582/20R2
KYHA1636 544718.1 8468549 1135.441 HA 4.5 23/10/2025 EL0582/20R2
KYHA1637 544667.7 8468649 1135.694 HA 6 23/10/2025 EL0582/20R2
KYHA1638 544766.7 8468650 1132.556 HA 5.45 23/10/2025 EL0582/20R2
KYHA1639 544668.83 8468851.6 1133.967 HA 4 23/10/2025 EL0582/20R2
KYHA1640 544768.33 8468850.5 1131.026 HA 0.49 24/10/2025 EL0582/20R2
KYHA1641 543850.6 8468701.5 1128.06 HA 2.1 24/10/2025 EL0582/20R2
KYHA1642 543750.19 8468599.7 1126.038 HA 1.8 24/10/2025 EL0582/20R2
KYHA1643 543649.27 8468699.7 1123.646 HA 1.13 24/10/2025 EL0582/20R2
KYHA1644 545006.79 8472238 1133.909 HA 4 28/10/2025 EL0582/20R2
KYHA1645 544810.16 8472170.8 1133.806 HA 3 28/10/2025 EL0582/20R2
KYHA1646 544807.59 8472270.2 1132.805 HA 4 29/10/2025 EL0582/20R2
KYHA1647 544811.5 8472468.1 1130.415 HA 5 29/10/2025 EL0582/20R2
KYHA1648 544810.84 8472369.6 1132.068 HA 3 29/10/2025 EL0582/20R2
KYHA1649 544611.46 8472446.2 1129.409 HA 8.5 29/10/2025 EL0582/20R2
KYHA1650 544611.24 8472341.5 1130.33 HA 5.5 30/10/2025 EL0582/20R2
KYHA1651 544612.19 8472248.4 1131.123 HA 6 30/10/2025 EL0582/20R2
KYHA1652 544611.23 8472153.5 1131.799 HA 4 30/10/2025 EL0582/20R2
KYHA1653 544411.48 8472368.6 1127.595 HA 4.2 30/10/2025 EL0582/20R2
KYHA1654 544409.47 8472267.3 1128.51 HA 4.5 30/10/2025 EL0582/20R2
KYHA1655 544410.03 8472172 1129.088 HA 4 30/10/2025 EL0582/20R2
KYHA1656 544212.45 8472173.3 1126.386 HA 6 30/10/2025 EL0582/20R2
KYHA1657 544209.71 8472279.6 1125.446 HA 4 31/10/2025 EL0582/20R2
KYHA1658 544039.41 8472201.7 1124.104 HA 5 31/10/2025 EL0582/20R2
KYHA_AC0280 544299.8 8468099.8 1142.4 HA 16 23/09/2024 EL0582
KYHA_AC0281 544499.7 8467900.7 1143.2 HA 15 23/09/2024 EL0582
KYHA_AC0282 544200.1 8466800.8 1153.4 HA 15 24/09/2024 EL0582
KYHA_AC0283 543900.9 8467500.1 1143.5 HA 16 24/09/2024 EL0582
KYHA_AC0284 543900.4 8466301.2 1152.2 HA 16 25/09/2024 EL0582
KYHA_AC0285 544300.6 8466499.9 1156.4 HA 16 25/09/2024 EL0582
KYHA_AC0286 545699.3 8465500.4 1164.8 HA 16 26/09/2024 EL0582
KYHA_AC0287 546099.5 8464901.7 1169.9 HA 16 26/09/2024 EL0582
KYHA_AC0288 545300.1 8465101.7 1165.1 HA 17 26/09/2024 EL0582
KYHA_AC0289 545300.3 8465700.7 1161.8 HA 10 26/09/2024 EL0582
KYHA_AC0290 543699.1 8467700.9 1139.2 HA 14 27/09/2024 EL0582
KYHA_AC0291 543300.1 8469701.8 1123.6 HA 16 30/09/2024 EL0582
KYHA_AC0292 543400.7 8470001.4 1117.2 HA 10 30/09/2024 EL0582
KYHA_AC0293 542899.3 8470101.6 1124.8 HA 15 30/09/2024 EL0582
KYHA_AC0294 543899.7 8471901.2 1124.7 HA 17 01/10/2024 EL0582
KYHA_AC0295 544701.1 8471501.1 1126.0 HA 17 01/10/2024 EL0582
KYHA_AC0296 544300.0 8470900.8 1122.2 HA 15 01/10/2024 EL0582
KYHA_AC0297 544300.3 8472100.4 1127.8 HA 17 02/10/2024 EL0582
KYHA_AC0298 543301.3 8471701.4 1119.9 HA 15 02/10/2024 EL0582
KYHA_AC0299 543900.6 8470499.3 1122.8 HA 16 02/10/2024 EL0582
KYHA_AC0300 543098.7 8471701.1 1115.1 HA 17 03/10/2024 EL0582
KYHA_AC0301 543396.3 8472401.1 1115.7 HA 14 03/10/2024 EL0609
KYHA_AC0302 543502.3 8472299.4 1117.8 HA 17 03/10/2024 EL0609
KYHA_AC0303 543801.1 8470000.9 1117.4 HA 11 02/10/2024 EL0582
KYHA_AC0304 543900.6 8469701.4 1123.2 HA 14 04/10/2024 EL0582
KYHA_AC0305 544300.9 8468899.7 1136.7 HA 17 07/10/2024 EL0582
KYHA_AC0306 546099.4 8467300.9 1161.9 HA 15 08/10/2024 EL0582
KYHA_AC0307 546486.3 8467899.1 1166.7 HA 12 09/10/2024 EL0582
KYHA_AC0308 543500.3 8468096.3 1127.7 HA 14 10/10/2024 EL0582
KYHA_AC0309 546099.6 8467706.7 1162.3 HA 17 11/10/2024 EL0582
KYPT0004 539598.1 8479601.2 1098.7 PT 14 23/09/2020 EL0609
KYPT0007 539601.0 8480000.4 1095.4 PT 13 23/09/2020 EL0609
KYPT0008 541602.8 8479597.5 1114.4 PT 14 25/09/2020 EL0609
KYPT0016 539601.2 8479999.3 1095.4 PT 8.5 01/10/2020 EL0609
KYPT0018 541196.1 8478395.4 1110.7 PT 13.9 02/10/2020 EL0609
KYPT0020 543597.9 8479601.6 1139.2 PT 13 03/10/2020 EL0609
KYPT0022 543162.8 8480370.1 1134.9 PT 13.5 05/10/2020 EL0609
KYPT0024 544003.4 8482398.2 1134.9 PT 11 05/10/2020 EL0609
KYPT0025 543200.6 8478001.2 1126.7 PT 11.8 06/10/2020 EL0609
KYPT0026 543200.2 8478000.6 1126.7 PT 10 06/10/2020 EL0609
KYPT0028 544000.1 8476798.4 1123.9 PT 11 07/10/2020 EL0609
KYPT0029 542000.1 8482398.6 1115.9 PT 10.9 08/10/2020 EL0609
KYPT0030 544004.1 8484001.7 1123.6 PT 9 08/10/2020 EL0609
KYPT0032 539198.5 8479600.2 1096.4 PT 12.8 09/10/2020 EL0609
KYPT0033 539599.9 8473601.5 1125.3 PT 13 10/10/2020 EL0609
KYPT0034 542000.4 8473600.1 1114.4 PT 12 10/10/2020 EL0609
KYPT0035 541600.7 8477201.5 1087.4 PT 8.7 11/10/2020 EL0609
KYPT0065 541399.2 8478999.3 1117.1 PT 13 12/07/2021 EL0609
KYPT0075 542598.6 8480199.4 1127.8 PT 11 14/07/2021 EL0609
KYPT0098 543799.1 8481399.3 1140.9 PT 13 20/07/2021 EL0609
KYPT0119 543004.2 8482202.6 1124.6 PT 10 24/07/2021 EL0609
KYPT0139 543800.8 8478602.5 1143.6 PT 13.7 29/07/2021 EL0609
KYPT0163 544199.9 8482599.8 1133.2 PT 8.5 03/08/2021 EL0609
KYPT0188 539800.6 8474400.9 1120.9 PT 13 10/08/2021 EL0609
KYPT0211 537000.4 8477799.3 1086.6 PT 11 18/08/2021 EL0492
KYPT0256 547792.7 8477400.1 1148.0 PT 12 01/07/2022 EL0609
KYPT0277 546195.9 8475402.9 1143.1 PT 11 07/07/2022 EL0582
KYPT0326 543000.9 8469802.7 1128.2 PT 9.22 19/07/2022 EL0582
KYPT0330 548999.7 8479394.3 1135.5 PT 8 11/06/2022 EL0609
KYPT0357 546601.5 8468200.3 1162.2 PT 14 09/08/2022 EL0582
KYPT0378 545798.9 8467800.5 1155.5 PT 14 14/08/2022 EL0582
KYPT0404 543798.7 8484602.0 1117.4 PT 10 19/08/2022 EL0609
KYPT0431 544999.0 8465798.8 1160.2 PT 10.6 27/08/2022 EL0582
KYPT0451 545805.0 8483800.0 1126.0 PT 9 06/09/2022 EL0609
KYSA0001 544264.3 8466436.3 1156.5 SA 15 28/10/2023 EL0582
KYSA0002 545203.9 8465392.4 1163.8 SA 18.77 29/10/2023 EL0582
KYSA0003 545188.8 8464977.3 1162.5 SA 17 30/10/2023 EL0582
KYSA0004 545342.9 8465610.0 1163.0 SA 20 30/10/2023 EL0582
KYSA0005 545938.7 8465730.3 1159.0 SA 19.62 31/10/2023 EL0582
KYSA0007 544158.0 8466997.0 1151.1 SA 12 02/11/2023 EL0582
KYSA0013 545245.2 8468438.9 1135.1 SA 6.6 05/11/2023 EL0582
KYSA0014 545189.9 8468917.2 1132.8 SA 13 06/11/2023 EL0582
KYSA0015 544251.5 8469119.6 1134.6 SA 10 06/11/2023 EL0582
KYSA0016 544258.1 8468779.7 1137.2 SA 16 06/11/2023 EL0582
KYSA0017 543512.5 8468319.0 1125.7 SA 15.45 07/11/2023 EL0582
KYSA0018 543497.5 8467582.8 1132.5 SA 12 07/11/2023 EL0582
KYSA0019 543512.3 8467918.9 1130.3 SA 14.4 08/11/2023 EL0582
KYSA0020 543911.7 8467925.8 1141.1 SA 17.9 08/11/2023 EL0582
KYSA0021 543925.3 8468325.2 1137.5 SA 17.63 01/12/2023 EL0582
KYSA0022 544219.6 8468361.0 1140.7 SA 17 10/11/2023 EL0582
KYSA0023 544258.4 8467926.1 1143.8 SA 18 10/11/2023 EL0582
KYSA0024 543803.9 8469770.9 1117.9 SA 12 11/11/2023 EL0582
KYSA0025 543691.8 8470265.5 1114.0 SA 10 12/11/2023 EL0582
KYSA0026 544051.7 8470849.2 1122.4 SA 15.75 12/11/2023 EL0582
KYSA0027 543988.9 8470403.1 1124.4 SA 14 13/11/2023 EL0582
KYSA0028 547250.0 8467214.7 1169.5 SA 8 13/11/2023 EL0582
KYSA0029 546587.3 8467493.3 1170.1 SA 18 13/11/2023 EL0582
KYSA0030 546988.0 8467493.0 1168.5 SA 16 14/11/2023 EL0582
KYSA0031 546184.9 8467595.2 1164.4 SA 15 15/11/2023 EL0582
KYSA0032 546800.3 8467899.7 1166.8 SA 10 15/11/2023 EL0582
KYSA0033 546398.7 8467906.0 1166.0 SA 18.5 15/11/2023 EL0582
KYSA0034 546832.1 8466692.7 1160.9 SA 15 01/12/2023 EL0582
KYSA0035 547070.8 8468620.3 1155.5 SA 10 16/11/2023 EL0582
KYSA0036 546604.3 8468573.1 1156.7 SA 15 17/11/2023 EL0582
KYSA0037 546135.8 8468668.8 1151.5 SA 14 17/11/2023 EL0582
KYSA0038 543199.6 8469505.2 1127.0 SA 14 18/11/2023 EL0582
KYSA0039 543200.2 8469904.8 1124.4 SA 14 18/11/2023 EL0582
KYSA0040 543202.6 8470284.5 1119.0 SA 15 19/11/2023 EL0582
KYSA0043 547150.9 8470004.0 1145.7 SA 12 20/11/2023 EL0582
KYSA0046 547228.8 8472516.5 1165.3 SA 6 22/11/2023 EL0582
KYSA0047 543789.1 8473001.4 1124.5 SA 10 22/11/2023 EL0609
KYSA0048 544005.3 8471901.3 1125.8 SA 10 22/11/2023 EL0582
KYSA0049 543600.0 8472300.5 1118.7 SA 14 23/11/2023 EL0609
KYSA0050 543600.1 8471500.0 1119.2 SA 14 23/11/2023 EL0582
KYSA0051 543601.3 8471901.0 1123.4 SA 20 23/11/2023 EL0582
KYSA0052 543221.1 8471103.3 1110.3 SA 12 30/11/2023 EL0582
KYSA0053 543208.8 8472303.0 1116.6 SA 10.66 25/11/2023 EL0609
KYSA0054 543199.3 8471899.4 1118.6 SA 9.59 25/11/2023 EL0582
KYSA0055 544404.7 8471902.8 1129.2 SA 17 26/11/2023 EL0582
KYSA0056 540159.6 8474394.7 1121.9 SA 14 27/11/2023 EL0609
KYSA0057 539600.5 8472966.0 1132.5 SA 11.8 27/11/2023 EL0609
KYSA0058 539189.4 8472834.8 1129.3 SA 8 28/11/2023 EL0609
KYSA0059 539795.5 8472529.4 1143.3 SA 14 28/11/2023 EL0609
KYSA0060 539004.3 8472150.0 1138.3 SA 12 29/11/2023 EL0609
KYSA0061 539737.1 8472024.5 1150.7 SA 12 29/11/2023 EL0609
KYSA0062 545200.4 8465395.1 1163.7 SA 19 15/12/2023 EL0582
KYSA0063 545635.0 8465502.8 1165.1 SA 20 16/12/2023 EL0582
KYSA0064 545341.4 8465615.2 1162.9 SA 19.9 17/12/2023 EL0582
KYSA0065 545937.6 8465731.6 1159.0 SA 19.75 18/12/2023 EL0582
KYSA0066 544259.5 8467923.9 1143.8 SA 16.55 19/12/2023 EL0582
KYSA0067 544220.6 8468364.7 1140.7 SA 17.15 19/12/2023 EL0582
KYSA0068 543796.6 8470000.8 1117.1 SA 15 11/12/2024 EL0582
KYSA0069 543899.2 8470501.7 1122.8 SA 21 29/11/2024 EL0582
KYSA0070 544268.4 8468343.9 1141.0 SA 18 12/02/2025 EL0582
KYSA0071 543899.6 8471893.8 1124.7 SA 18 17/02/2025 EL0582
KYSA0072 543098.2 8471699.8 1115.1 SA 15 22/02/2025 EL0582
KYSA0073 543300.2 8471700.8 1119.9 SA 14 25/02/2025 EL0582
KYSA0074 542607.8 8480420.7 1126.5 SA 16 07/03/2025 EL0609
KYSA0075 544400.4 8481199.2 1142.3 SA 20 10/03/2025 EL0609
KYSA0076 543997.9 8480803.0 1145.4 SA 17.4 14/03/2025 EL0609
KYSA0077 544403.7 8480441.0 1145.1 SA 18 18/03/2025 EL0609
KYSA0078 543799.2 8479397.7 1143.8 SA 17.7 22/03/2025 EL0609
KYSA0079 543584.3 8478038.9 1132.3 SA 17 26/03/2025 EL0609
KYSA0080 543668.0 8473109.3 1122.0 SA 12.3 31/03/2025 EL0609
KYSA0081 544077.4 8473313.1 1125.9 SA 15.3 04/04/2025 EL0582
KYSA0082 543599.26 8472000 1122.584 SA 21 06/06/2025 EL0582/20R2
KYSA0083 543699.56 8471900.4 1124.093 SA 17.5 07/06/2025 EL0582/20R2
KYSA0084 546399.92 8467599.7 1167.877 SA 17 01/07/2025 EL0582/20R2
KYSA0085 546301.01 8467504.7 1166.625 SA 15 02/07/2025 EL0582/20R2
KYSA0086 545500.29 8465499.5 1164.912 SA 14 04/07/2025 EL0582/20R2
KYSA0087 545600.49 8465400.5 1166.382 SA 18 05/07/2025 EL0582/20R2
KYSA0088 544299.58 8471701.1 1125.516 SA 8 05/08/2025 EL0582/20R2
KYSA0089 544298.82 8471701.4 1125.502 SA 8 05/08/2025 EL0582/20R2
KYSA0090 544700.45 8472098.5 1132.54 SA 8 06/08/2025 EL0582/20R2
KYSA0091 544701.35 8472098.4 1132.545 SA 8 06/08/2025 EL0582/20R2
KYSA0092 543299.5 8472102.2 1120.736 SA 8 07/08/2025 EL0609
KYSA0093 543298.58 8472102.2 1120.707 SA 8 07/08/2025 EL0609
KYSA0094 543499.1 8471502.7 1119.67 SA 8 07/08/2025 EL0582/20R2
KYSA0095 543498.25 8471503 1119.675 SA 8 07/08/2025 EL0582/20R2
KYSA0096 543200.58 8470201 1120.584 SA 8 08/08/2025 EL0582/20R2
KYSA0097 543200.32 8470201.8 1120.568 SA 8 09/08/2025 EL0582/20R2
KYSA0098 543100.6 8469901.5 1126.002 SA 8 09/08/2025 EL0582/20R2
KYSA0099 543101.17 8469901.3 1126.001 SA 8 09/08/2025 EL0582/20R2
KYSA0100 543399.94 8469601.3 1121.301 SA 7 11/08/2025 EL0582/20R2
KYSA0101 543399.19 8469601.5 1121.331 SA 7 11/08/2025 EL0582/20R2
KYSA0102 543900.34 8468102.1 1139.316 SA 8 12/08/2025 EL0582/20R2
KYSA0103 543900.92 8468101.8 1139.329 SA 8 12/08/2025 EL0582/20R2
KYSA0104 544499.43 8468698.3 1137.411 SA 8 13/08/2025 EL0582/20R2
KYSA0105 544500.21 8468698.1 1137.408 SA 8 13/08/2025 EL0582/20R2
KYSA0106 543500.9 8472098.5 1121.139 SA 4 26/09/2025 EL0609
KYSA0107 543301.6 8472300.2 1117.721 SA 6 26/09/2025 EL0609
KYSA0108 543099.82 8472300.1 1114.381 SA 4 27/09/2025 EL0609
KYSA0109 542899.43 8472298.9 1106.313 SA 2 27/09/2025 EL0609
KYSA0110 543099.56 8472100.4 1115.984 SA 2 27/09/2025 EL0609
KYSA0111 542898.33 8472099.8 1107.421 SA 5 27/09/2025 EL0609
KYSA0112 542999.22 8472000.7 1112.21 SA 2 27/09/2025 EL0609
KYSA0113 543098.72 8471899.9 1115.851 SA 4 27/09/2025 EL0582/20R2
KYSA0114 543300.43 8471901.5 1120.634 SA 4 27/09/2025 EL0582/20R2
KYSA0115 543699.65 8472100.5 1122.221 SA 4 27/09/2025 EL0609
KYSA0116 544100.45 8472099.8 1126.149 SA 6 28/09/2025 EL0582/20R2
KYSA0117 544498.62 8472098.4 1130.361 SA 4 29/09/2025 EL0582/20R2
KYSA0118 544500.63 8472299.9 1129.701 SA 4 29/09/2025 EL0582/20R2
KYSA0119 544600.42 8472400.6 1129.853 SA 2 29/09/2025 EL0582/20R2
KYSA0120 544699.21 8472299.1 1132.129 SA 4 29/09/2025 EL0582/20R2
KYSA0121 544700.19 8472500.7 1128.908 SA 4 29/09/2025 EL0582/20R2
KYSA0122 544900 8472499.2 1130.225 SA 2 29/09/2025 EL0582/20R2
KYSA0123 544999.57 8472399.9 1132.193 SA 4 29/09/2025 EL0582/20R2
KYSA0124 544900.18 8472300.9 1133.078 SA 2 29/09/2025 EL0582/20R2
KYSA0125 544800.46 8472200.7 1133.236 SA 4 29/09/2025 EL0582/20R2
KYSA0126 544900.13 8472098.7 1133.893 SA 4 30/09/2025 EL0582/20R2
KYSA0127 545099.51 8472099.9 1131.893 SA 2 30/09/2025 EL0582/20R2
KYSA0128 544500.51 8467699.9 1144.328 SA 6 13/10/2025 EL0582/20R2
KYSA0129 544600.59 8467600.5 1144.578 SA 6 13/10/2025 EL0582/20R2
KYSA0130 544499.39 8467500.1 1145.967 SA 6 13/10/2025 EL0582/20R2
KYSA0131 544198.79 8467600 1145.409 SA 6 13/10/2025 EL0582/20R2
KYSA0132 544298.45 8467699.8 1145.512 SA 6 13/10/2025 EL0582/20R2
KYSA0133 544098.72 8467900 1143.194 SA 4 13/10/2025 EL0582/20R2
KYSA0134 544293.49 8468300.3 1141.361 SA 4 13/10/2025 EL0582/20R2
KYSA0135 544100.79 8468300.6 1139.739 SA 6 14/10/2025 EL0582/20R2
KYSA0136 544102.51 8468100.1 1141.537 SA 4 14/10/2025 EL0582/20R2
KYSA0137 544499.52 8468100.7 1141.672 SA 6 14/10/2025 EL0582/20R2
KYSA0138 544500.39 8468299.5 1140.57 SA 6 14/10/2025 EL0582/20R2
KYSA0139 544698.44 8468500.6 1136.525 SA 6 14/10/2025 EL0582/20R2
KYSA0140 544499.26 8468501 1139.276 SA 6 14/10/2025 EL0582/20R2
KYSA0141 544700.43 8468700 1134.664 SA 6 15/10/2025 EL0582/20R2
KYSA0142 544499.5 8468900 1136.031 SA 6 15/10/2025 EL0582/20R2
KYSA0143 544699.36 8468901.1 1133.188 SA 6 15/10/2025 EL0582/20R2
KYSA0144 544797.7 8468999.7 1129.283 SA 4 15/10/2025 EL0582/20R2
KYSA0145 544299.7 8468701 1137.895 SA 4 16/10/2025 EL0582/20R2
KYSA0146 544299.3 8468499 1139.458 SA 4 16/10/2025 EL0582/20R2
KYSA0147 544099.1 8468501 1137.85 SA 4 16/10/2025 EL0582/20R2
KYSA0148 543698.8 8468100 1134.276 SA 2 16/10/2025 EL0582/20R2
KYSA0149 543699.4 8467897 1137.451 SA 6 16/10/2025 EL0582/20R2
KYSA0150 543898.4 8467700 1142.328 SA 6 16/10/2025 EL0582/20R2
KYSA0151 544098.71 8467699.9 1144.386 SA 6 16/10/2025 EL0582/20R2
KYSA0152 543401.3 8467799.6 1128.851 SA 4 17/10/2025 EL0582/20R2
KYSA0153 543499.23 8467701.7 1131.563 SA 4 17/10/2025 EL0582/20R2
KYSA0154 543500.14 8467501.3 1134.112 SA 4 17/10/2025 EL0582/20R2
KYSA0155 543601.64 8467401.9 1138.808 SA 2.3 17/10/2025 EL0582/20R2
KYSA0156 543699.78 8467499.7 1139.996 SA 4 17/10/2025 EL0582/20R2
KYSA0157 543699.57 8467302 1141.782 SA 4 17/10/2025 EL0582/20R2
KYSA0158 543800.13 8467202.3 1144.448 SA 6 17/10/2025 EL0582/20R2
KYSA0159 543900.47 8467305.3 1144.816 SA 4 17/10/2025 EL0582/20R2
KYSA0160 543900.35 8467100.2 1146.736 SA 6 18/10/2025 EL0582/20R2
KYSA0161 543699.9 8467100.1 1143.494 SA 4 18/10/2025 EL0582/20R2
KYSA0162 543699.93 8466699.9 1147.031 SA 6 18/10/2025 EL0582/20R2
KYSA0163 543600.1 8466600 1145.703 SA 6 18/10/2025 EL0582/20R2
KYSA0164 543700.1 8466900.1 1145.587 SA 4 18/10/2025 EL0582/20R2
KYSA0165 543800.28 8466800.3 1148.134 SA 4 18/10/2025 EL0582/20R2
KYSA0166 543899.35 8466900.4 1148.93 SA 4 18/10/2025 EL0582/20R2
KYSA0167 543899.5 8466700 1150.841 SA 4 18/10/2025 EL0582/20R2
KYSA0168 544099.5 8466700 1153.57 SA 4 18/10/2025 EL0582/20R2
KYSA0169 544100.8 8466899 1151.664 SA 6 20/10/2025 EL0582/20R2
KYSA0170 544000.6 8467000 1149.208 SA 6 20/10/2025 EL0582/20R2
KYSA0171 544099.8 8467101 1149.63 SA 6 20/10/2025 EL0582/20R2
KYSA0172 544198.53 8467204.8 1149.292 SA 6 21/10/2025 EL0582/20R2
KYSA0173 544299.68 8467100.6 1150.444 SA 6 21/10/2025 EL0582/20R2
KYSA0174 544500.12 8467099.7 1149.545 SA 4 21/10/2025 EL0582/20R2
KYSA0175 544599.34 8467200.3 1147.911 SA 4 21/10/2025 EL0582/20R2
KYSA0176 544699.83 8467294.1 1144.844 SA 4 21/10/2025 EL0582/20R2
KYSA0177 544499.67 8467300.1 1147.879 SA 4 21/10/2025 EL0582/20R2
KYSA0178 544399.68 8467400 1147.592 SA 4 21/10/2025 EL0582/20R2
KYSA0179 544299.56 8467500.1 1146.435 SA 4 21/10/2025 EL0582/20R2
KYSA0180 544099.62 8467500 1145.427 SA 6 22/10/2025 EL0582/20R2
KYSA0181 544299.63 8467299.9 1148.747 SA 6 22/10/2025 EL0582/20R2
KYSA0182 544099.02 8467300.1 1147.481 SA 4 22/10/2025 EL0582/20R2
NSHA0004 543599.9 8471600.1 1121.2 HA 11.5 28/10/2020 EL0582
NSHA0005 543999.5 8470800.0 1122.3 HA 12 28/10/2020 EL0582
NSHA0009 543599.9 8468399.9 1127.0 HA 9 29/10/2020 EL0582
NSHA0010 544399.9 8468400.1 1140.3 HA 5 30/10/2020 EL0582
NSHA0012 546000.0 8467599.9 1161.3 HA 9 30/10/2020 EL0582
NSHA0036 544005.2 8471600.0 1121.5 HA 10 08/12/2020 EL0582
NSHA0056 544400.0 8469200.0 1135.3 HA 10 10/12/2020 EL0582
NSHA0073 543599.3 8467597.7 1136.5 HA 8 19/12/2020 EL0582
NSHA0224 545600.1 8465200.5 1167.8 HA 10 24/05/2021 EL0582
NSHA0225 545200.0 8465200.0 1163.7 HA 12 24/05/2021 EL0582
NSHA0261 543999.9 8471998.4 1125.4 HA 12 08/06/2021 EL0582
NSHA0262 543600.0 8471997.9 1122.6 HA 13 08/06/2021 EL0582
NSHA0263 543198.7 8471997.2 1118.7 HA 9 08/06/2021 EL0582
NSHA0289 544400.0 8471600.0 1124.8 HA 10 06/07/2021 EL0582
NSHA0290 544001.2 8471199.3 1112.5 HA 8 07/07/2021 EL0582
NSHA0297 544000.0 8470400.0 1124.6 HA 12 07/07/2021 EL0582
NSHA0311 544400.1 8468800.4 1137.3 HA 12 09/07/2021 EL0582
NSHA0316 546400.2 8468000.2 1164.0 HA 12 15/07/2021 EL0582
NSHA0344 544399.3 8467997.9 1143.3 HA 12 24/07/2021 EL0582
NSHA0345 544001.9 8468004.4 1141.4 HA 10 24/07/2021 EL0582
NSHA0350 543601.4 8468000.9 1132.0 HA 11 27/07/2021 EL0582
NSHA0359 545997.2 8466401.0 1147.1 HA 6 29/07/2021 EL0582
NSHA0360 546001.2 8465997.6 1151.8 HA 9 29/07/2021 EL0582
NSHA0363 545199.9 8465600.4 1162.5 HA 13 02/08/2021 EL0582
NSHA0364 545600.2 8465601.0 1163.3 HA 12 30/07/2021 EL0582
NSHA0398 546597.0 8475000.4 1143.0 HA 9 26/01/2022 EL0582
NSHA0399 547005.0 8475798.3 1152.2 HA 11 26/01/2022 EL0582
NSHA0400 543799.5 8471801.0 1124.0 HA 11 26/01/2022 EL0582
NSHA0401 544599.0 8472201.3 1131.5 HA 12 26/01/2022 EL0582
NSHA0402 544201.9 8469000.3 1135.4 HA 12 27/01/2022 EL0582
NSHA0403 544200.7 8468600.3 1137.9 HA 11 27/01/2022 EL0582
NSHA0404 544600.1 8467800.6 1142.9 HA 11 27/01/2022 EL0582
NSHA0405 545400.2 8465400.2 1165.4 HA 13 27/01/2022 EL0582
NSPT0022 544594.3 8468998.7 1134.8 PT 11 02/09/2021 EL0582
NSPT0041 546598.4 8475797.3 1149.0 PT 12.75 08/09/2021 EL0582
OBSAC0013 541792.7 8467522.0 1152.3 AC 35 13/12/2023 EL0582
OBSAC-02 547004.2 8474993.8 1149.2 AC 16.54 07/09/2022 EL0582
OBSAC-07 540197.1 8479600.4 1101.8 AC 24 07/09/2022 EL0609
OBSAC-08 539540.8 8472407.3 1152.8 AC 17.5 07/09/2022 EL0609
OBSDD_01A 548595.3 8478602.3 1141.1 DD 13.06 23/07/2025 EL0609
OBSDD_01B 548592.3 8478590.8 1141.1 DD 25 23/07/2025 EL0609
OBSDD_03 546603.8 8467803.5 1168.2 DD 35 23/07/2025 EL0582
OBSDD_04 545195.7 8465397.9 1163.6 DD 30 23/07/2025 EL0582
OBSDD_05 543999.2 8468195.2 1139.4 DD 40 23/07/2025 EL0582
OBSDD_06 543803.7 8471799.1 1124.0 DD 30 23/07/2025 EL0582
REHAB3PT0001 544179.6 8468402.2 1139.3 PT 5 15/01/2025 EL0582
REHAB3PT0002 544185.9 8468398.4 1139.6 PT 5 15/01/2025 EL0582
REHAB3PT0003 544190.9 8468403.8 1139.4 PT 5 16/01/2025 EL0582
REHAB3PT0004 544189.6 8468393.8 1139.8 PT 5 16/01/2025 EL0582
REHAB3PT0005 544182.4 8468393.8 1139.6 PT 5 14/01/2025 EL0582
REHAB4PT0001 544156.8 8468402.9 1139.4 PT 5 14/01/2025 EL0582
REHAB4PT0002 544161.3 8468399.7 1139.4 PT 4.86 14/01/2025 EL0582
REHAB4PT0003 544167.0 8468404.8 1139.3 PT 4.89 14/01/2025 EL0582
REHAB4PT0004 544159.1 8468395.3 1139.4 PT 5 15/01/2025 EL0582
REHAB4PT0005 544168.3 8468398.2 1139.4 PT 5 15/01/2025 EL0582
RGHA0059 552766.5 8483099.3 1110.8 HA 4 05/10/2022 EL0609
RGHA0060 553600.9 8483102.2 1125.1 HA 9 05/10/2022 EL0609
RGHA0066 564798.5 8495002.3 1214.6 HA 12 12/10/2022 EL0492
RGHA0067 564028.0 8494992.5 1194.9 HA 5 12/10/2022 EL0492
RGHA0072 557599.3 8490401.4 1139.6 HA 12 18/10/2022 EL0492
RGHA0073 560803.3 8490399.3 1175.6 HA 6 18/10/2022 EL0492
RGHA0074 558399.5 8490399.8 1152.4 HA 11 19/10/2022 EL0492
RGHA0075 559196.4 8490401.8 1159.1 HA 9 19/10/2022 EL0492
RGHA0076 559998.7 8490398.7 1160.3 HA 6 19/10/2022 EL0492
RGHA0077 561597.2 8490397.6 1196.8 HA 10 19/10/2022 EL0492
RGHA0116 536772.9 8473185.2 1114.2 HA 7 12/01/2024 EL0609
RGHA0120 536801.9 8473595.6 1119.2 HA 14 13/01/2024 EL0609
RGHA0123 536794.7 8473999.8 1121.6 HA 11 14/01/2024 EL0609
RGHA0124 536393.0 8474035.6 1116.7 HA 13 14/01/2024 EL0609
RGHA0125 537200.1 8474604.2 1112.6 HA 14 14/01/2024 EL0609
RGHA0126 540823.3 8472401.0 1127.9 HA 12 17/01/2024 EL0609
RGHA0127 541208.8 8472399.6 1124.9 HA 11 17/01/2024 EL0609
RGHA0129 542006.3 8472399.2 1111.0 HA 8 17/01/2024 EL0609
RGHA0130 539298.2 8468398.7 1140.2 HA 4 18/01/2024 EL0609
RGHA0133 539295.4 8467221.0 1144.8 HA 12 22/01/2024 EL0609
RGHA0138 545603.5 8485201.1 1118.0 HA 12 24/01/2024 EL0609
RGHA0139 545998.6 8485601.9 1119.3 HA 12 24/01/2024 EL0609
RGHA0140 545226.4 8485603.5 1112.4 HA 3 24/01/2024 EL0609
RGHA0141 545210.6 8485222.6 1115.7 HA 12 24/01/2024 EL0609
RGHA0150 550011.5 8481598.1 1134.4 HA 12 26/01/2024 EL0609
RGHA0151 550403.5 8481617.3 1131.3 HA 12 27/01/2024 EL0609
RGHA0154 552000.3 8481594.5 1104.5 HA 6 29/01/2024 EL0609
RGHA0156 553199.8 8481610.9 1112.6 HA 3 31/01/2024 EL0609
RGHA0157 552391.8 8480799.1 1121.4 HA 12 30/01/2024 EL0609
RGHA0159 551554.0 8480823.2 1111.2 HA 7 30/01/2024 EL0609
RGHA0160 551618.8 8480400.2 1121.8 HA 4 30/01/2024 EL0609
RGHA0161 551232.3 8480389.5 1115.5 HA 2 30/01/2024 EL0609
RGHA0162 551193.5 8480827.7 1103.2 HA 3 30/01/2024 EL0609
RGHA0164 550411.4 8480821.1 1122.2 HA 1 30/01/2024 EL0609
RGHA0165 550003.7 8480799.3 1127.2 HA 11 31/01/2024 EL0609
RGHA0166 554002.0 8484403.3 1109.5 HA 3 31/01/2024 EL0609
RGHA0167 553218.1 8484382.0 1119.6 HA 12 31/01/2024 EL0609
RGHA0170 551198.8 8481601.5 1120.0 HA 9 29/01/2024 EL0609
RGHA0171 539708.9 8469597.0 1147.1 HA 12 07/02/2024 EL0609
RGHA0173 538502.0 8467199.5 1137.7 HA 12 07/02/2024 EL0609
RGHA0174 538898.4 8467200.5 1141.4 HA 12 07/02/2024 EL0609
RGHA0175 538500.2 8468401.6 1131.6 HA 12 09/02/2024 EL0609
RGHA0176 538870.4 8468423.7 1135.0 HA 9 09/02/2024 EL0609
RGHA0194 542403.5 8461207.3 1149.0 HA 11 16/02/2024 EL0609
RGHA0195 542810.0 8461212.6 1154.2 HA 12 16/02/2024 EL0609
RGHA0275 567005.0 8505200.6 1170.4 HA 12 13/03/2024 EL0492
RGHA0276 567402.4 8505202.1 1169.7 HA 12 13/03/2024 EL0492
RGHA0277 567802.3 8505207.9 1165.9 HA 12 13/03/2024 EL0492
RGHA0278 566998.6 8504403.6 1165.5 HA 11 13/03/2024 EL0492
RGHA0279 567402.4 8504404.1 1161.9 HA 10 13/03/2024 EL0492
RGHA0280 567800.5 8504439.1 1155.4 HA 5 13/03/2024 EL0492
RGHA0281 562599.0 8503205.8 1160.5 HA 3 13/03/2024 EL0492
RGHA0282 563400.0 8503200.0 1168.9 HA 9 13/03/2024 EL0492
RGHA0283 564200.4 8503199.6 1177.0 HA 7 13/03/2024 EL0492
RGHA0284 564998.6 8503200.8 1178.0 HA 9 13/03/2024 EL0492
RGHA0285 568603.3 8503997.3 1159.1 HA 3 14/03/2024 EL0492
RGHA0286 569004.0 8504008.3 1165.4 HA 12 14/03/2024 EL0492
RGHA0287 569394.9 8504004.3 1166.0 HA 8 14/03/2024 EL0492
RGHA0288 569796.1 8504002.4 1160.1 HA 12 14/03/2024 EL0492
RGHA0289 568597.9 8503601.0 1165.0 HA 2 14/03/2024 EL0492
RGHA0290 567400.5 8503201.0 1170.0 HA 6 14/03/2024 EL0492
RGHA0291 567802.6 8503206.1 1173.6 HA 8 14/03/2024 EL0492
RGHA0292 568203.9 8503208.1 1176.0 HA 9 14/03/2024 EL0492
RGHA0293 568595.9 8503213.7 1174.6 HA 4 14/03/2024 EL0492
RGHA0294 568999.9 8503186.6 1175.2 HA 11 14/03/2024 EL0492
RGHA0295 569400.0 8503199.9 1170.2 HA 12 15/03/2024 EL0492
RGHA0296 569800.4 8503200.2 1155.7 HA 4 15/03/2024 EL0492
RGHA0297 570602.7 8502410.2 1161.5 HA 9 15/03/2024 EL0492
RGHA0298 570201.3 8502398.4 1166.0 HA 12 15/03/2024 EL0492
RGHA0299 569788.8 8502448.2 1158.9 HA 5 15/03/2024 EL0492
RGHA0300 569399.8 8502364.4 1169.3 HA 5 15/03/2024 EL0492
RGHA0301 568992.2 8502446.6 1174.9 HA 5 19/03/2024 EL0492
RGHA0302 567013.1 8502804.2 1172.3 HA 3 18/03/2024 EL0492
RGHA0303 567399.9 8502800.2 1180.2 HA 12 18/03/2024 EL0492
RGHA0304 567801.5 8502804.4 1183.7 HA 12 18/03/2024 EL0492
RGHA0305 568207.1 8502800.6 1184.4 HA 12 18/03/2024 EL0492
RGHA0306 568603.4 8502806.1 1181.4 HA 12 18/03/2024 EL0492
RGHA0307 569008.1 8502796.0 1177.4 HA 12 19/03/2024 EL0492
RGHA0308 568603.3 8502399.5 1184.1 HA 3 19/03/2024 EL0492
RGHA0309 567004.0 8502001.8 1183.8 HA 5 19/03/2024 EL0492
RGHA0310 567024.0 8502408.7 1177.9 HA 3 19/03/2024 EL0492
RGHA0311 567402.2 8502006.5 1193.6 HA 12 19/03/2024 EL0492
RGHA0312 567796.8 8502007.9 1203.0 HA 11 20/03/2024 EL0492
RGHA0313 568205.4 8502012.4 1193.0 HA 12 20/03/2024 EL0492
RGHA0314 568600.5 8502003.3 1186.2 HA 7 20/03/2024 EL0492
RGHA0316 565800.5 8506402.0 1162.4 HA 12 20/03/2024 EL0492
RGHA0318 564202.0 8506399.1 1156.3 HA 5 20/03/2024 EL0492
RGHA0326 563800.4 8510408.9 1124.1 HA 8 21/03/2024 EL0492
RGHA0328 562200.4 8510401.3 1131.9 HA 11 22/03/2024 EL0492
RGHA0329 566201.0 8513408.1 1126.2 HA 4 21/03/2024 EL0492
RGHA0330 565384.1 8513404.1 1119.4 HA 3 21/03/2024 EL0492
RGHA0331 564601.2 8513405.6 1110.7 HA 10 21/03/2024 EL0492
RGHA0333 563007.6 8513414.6 1131.0 HA 12 22/03/2024 EL0492
RGHA0334 562208.5 8513406.9 1136.7 HA 12 22/03/2024 EL0492
RGHA0335 561805.4 8516206.3 1130.5 HA 10 25/03/2024 EL0492
RGHA0336 561411.1 8515411.7 1130.0 HA 8 25/03/2024 EL0492
RGHA0337 561795.2 8515416.0 1136.0 HA 12 25/03/2024 EL0492
RGHA0338 562197.9 8515407.0 1140.1 HA 7 25/03/2024 EL0492
RGHA0339 560993.1 8517399.1 1112.2 HA 6 26/03/2024 EL0492
RGHA0340 561400.4 8517405.5 1122.7 HA 9 26/03/2024 EL0492
RGHA0341 561800.6 8517401.4 1129.9 HA 6 26/03/2024 EL0492
RGHA0342 562228.9 8517407.9 1127.6 HA 4 26/03/2024 EL0492
RGHA0343 561800.7 8516609.9 1131.9 HA 4 26/03/2024 EL0492
RGHA0344 562196.1 8516611.3 1131.1 HA 5 26/03/2024 EL0492
RGHA0345 562203.9 8516208.7 1134.7 HA 12 27/03/2024 EL0492
RGHA0346 565003.0 8499605.2 1209.3 HA 9 27/03/2024 EL0492
RGHA0347 564604.8 8499606.4 1201.3 HA 9 27/03/2024 EL0492
RGHA0348 565402.1 8499611.0 1204.7 HA 12 27/03/2024 EL0492
RGHA0351 563203.0 8495003.9 1180.2 HA 3 27/03/2024 EL0492
RGHA0352 559205.0 8492806.5 1163.1 HA 12 27/03/2024 EL0492
RGHA0353 560005.9 8492807.8 1166.5 HA 12 27/03/2024 EL0492
RGHA0354 560794.6 8492809.9 1167.5 HA 6 27/03/2024 EL0492
RGHA0355 561599.7 8492800.6 1174.4 HA 5 27/03/2024 EL0492
RGHA0356 562400.0 8492799.9 1184.9 HA 6 27/03/2024 EL0492
RGHA0357 563200.2 8492803.5 1194.4 HA 7 27/03/2024 EL0492
RGHA0358 563998.9 8492807.0 1196.5 HA 7 27/03/2024 EL0492
RGHA0360 546400.8 8487602.0 1111.6 HA 7 10/04/2024 EL0492
RGHA0361 546803.2 8487606.8 1114.4 HA 6 10/04/2024 EL0492
RGHA0362 546000.5 8487203.2 1106.2 HA 4 10/04/2024 EL0492
RGHA0363 546800.1 8487204.6 1115.8 HA 10 10/04/2024 EL0492
RGHA0366 547601.1 8488800.3 1102.1 HA 2 11/04/2024 EL0492
RGHA0367 547602.8 8488447.1 1106.3 HA 1 11/04/2024 EL0492
RGHA0368 547601.5 8488003.4 1110.5 HA 10 11/04/2024 EL0492
RGHA0369 547600.5 8487603.2 1112.2 HA 12 11/04/2024 EL0492
RGHA0370 547596.6 8487199.8 1110.9 HA 12 12/04/2024 EL0492
RGHA0375 550298.1 8485971.8 1080.1 HA 5 16/04/2024 EL0609
RGHA0376 550002.2 8485999.0 1089.0 HA 8 16/04/2024 EL0609
RGHA0377 549601.5 8485998.0 1095.4 HA 9 16/04/2024 EL0609
RGHA0411 552795.5 8489600.2 1093.0 HA 6 30/04/2024 EL0492
RGHA0413 552000.0 8489599.9 1105.5 HA 12 30/04/2024 EL0492
RGHA0415 551200.0 8489600.0 1099.6 HA 10 30/04/2024 EL0492
RGHA0417 550400.9 8489598.5 1086.5 HA 10 30/04/2024 EL0492
RGHA0420 551200.0 8489200.5 1106.6 HA 12 03/05/2024 EL0492
RGHA0421 551607.6 8489211.1 1111.9 HA 12 03/05/2024 EL0492
RGHA0525 542112.2 8460922.2 1140.6 HA 5 27/05/2024 EL0609
RGHA0526 542512.9 8460922.0 1148.3 HA 11 27/05/2024 EL0609
RGHA0530 542294.9 8461636.4 1146.6 HA 9 28/05/2024 EL0609
RGHA0536 534400.4 8469198.2 1105.4 HA 11 28/05/2024 EL0609
RGHA0542 550018.3 8482002.0 1132.8 HA 12 30/05/2024 EL0609
RGHA0543 550416.2 8482008.0 1130.0 HA 7 30/05/2024 EL0609
RGHA0553 551607.6 8481200.0 1101.1 HA 5 03/06/2024 EL0609
RGHA0554 551208.0 8481200.7 1113.6 HA 10 03/06/2024 EL0609
RGHA0557 550008.0 8481200.0 1133.3 HA 11 04/06/2024 EL0609
RGHA0629 539601.9 8467999.8 1144.2 HA 2 18/07/2024 EL0609
RGHA0630 539599.4 8468411.4 1145.2 HA 6 18/07/2024 EL0609
RGHA0631 539600.2 8468799.8 1148.9 HA 12 18/07/2024 EL0609
RGHA0632 539996.0 8468801.0 1155.3 HA 12 18/07/2024 EL0609
RGHA0638 545999.7 8461800.0 1186.3 HA 12 23/07/2024 EL0582
RGHA0664 538800.3 8466399.8 1127.8 HA 7 02/08/2024 EL0609
RGHA0665 539197.6 8466398.4 1130.7 HA 6 02/08/2024 EL0609
RGHA0666 550405.5 8488808.9 1089.8 HA 7 23/10/2024 EL0492
RGHA0667 550799.7 8488804.0 1100.1 HA 12 23/10/2024 EL0492
RGHA0668 551200.1 8488800.0 1108.6 HA 10 23/10/2024 EL0492
RGHA0669 550402.3 8488402.9 1096.6 HA 10 24/10/2024 EL0492
RGHA0670 550804.7 8488399.9 1100.0 HA 12 24/10/2024 EL0492
RGHA0671 551200.9 8488400.2 1106.2 HA 4 24/10/2024 EL0492
RGHA0672 550403.5 8488000.0 1100.3 HA 12 24/10/2024 EL0492
RGHA0673 551999.9 8488000.1 1118.1 HA 14 10/07/2025 EL0492
RGHA0674 552400.1 8488400.6 1122.5 HA 16 10/07/2025 EL0492
RGHA0675 551600.0 8488000.0 1111.3 HA 14 10/07/2025 EL0492
RGHA0676 550803.3 8488001.5 1103.4 HA 13 10/07/2025 EL0492
RGHA0677 550799.8 8487201.2 1101.8 HA 8 11/07/2025 EL0492
RGHA0678 550800.3 8486800.4 1100.8 HA 12 11/07/2025 EL0492
RGHA0679 550797.7 8486403.5 1094.2 HA 11 11/07/2025 EL0492
RGHA0680 551199.9 8486411.3 1084.4 HA 4 14/07/2025 EL0492
RGHA0681 550399.0 8487601.0 1100.4 HA 12 14/07/2025 EL0492
RGHA0682 550400.0 8487200.0 1097.0 HA 2 14/07/2025 EL0492
RGHA0683 550400.0 8486800.0 1095.0 HA 1.5 14/07/2025 EL0492
RGHA0684 550799.7 8487603.1 1103.2 HA 12 14/07/2025 EL0492
RGHA0685 550400.0 8486400.0 1087.2 HA 3 14/07/2025 EL0492
RGHA0686 550000.0 8487200.0 1090.9 HA 12 15/07/2025 EL0492
RGHA0687 550000.0 8486799.9 1079.0 HA 6 15/07/2025 EL0492
RGHA0691 555797.9 8491403.3 1121.5 HA 8 16/07/2025 EL0492
RGHA0692 556596.3 8491405.4 1127.4 HA 10 16/07/2025 EL0492
RGHA0693 558005.0 8490404.9 1146.8 HA 13 16/07/2025 EL0492
RGHA0694 558803.1 8490405.7 1156.6 HA 12 16/07/2025 EL0492
RGHA0695 559598.6 8490408.8 1159.2 HA 10 16/07/2025 EL0492
RGHA0696 560402.3 8490408.2 1166.5 HA 8 17/07/2025 EL0492
RGHA0697 561205.1 8490408.1 1186.6 HA 12 17/07/2025 EL0492
RGHA0698 562003.0 8490408.3 1203.1 HA 12 17/07/2025 EL0492
RGHA0699 562810.2 8490400.5 1210.4 HA 12 17/07/2025 EL0492
RGHA0700 558998.4 8491401.8 1160.3 HA 9 17/07/2025 EL0492
RGHA0701 559795.6 8491405.9 1164.9 HA 12 17/07/2025 EL0492
RGHA0702 560606.7 8491402.0 1173.0 HA 11 18/07/2025 EL0492
RGHA0703 561401.0 8491406.0 1186.1 HA 12 18/07/2025 EL0492
RGHA0704 562207.0 8491406.0 1197.8 HA 4.7 18/07/2025 EL0492
RGHA0705 563001.0 8491395.0 1204.8 HA 12 18/07/2025 EL0492
RGHA0708 559997.9 8493610.0 1163.2 HA 11 22/07/2025 EL0492
RGHA0709 560803.7 8493604.0 1165.6 HA 12 22/07/2025 EL0492
RGHA0710 561602.0 8493608.0 1171.4 HA 11 22/07/2025 EL0492
RGHA0711 562404.1 8493613.0 1179.8 HA 8 22/07/2025 EL0492
RGHA0712 563201.7 8493608.0 1187.4 HA 10 22/07/2025 EL0492
RGHA0713 564004.0 8493600.0 1195.2 HA 4 22/07/2025 EL0492
RGHA0715 560602.9 8494213.0 1163.3 HA 12 23/07/2025 EL0492
RGHA0716 561396.7 8494210.0 1168.7 HA 8 23/07/2025 EL0492
RGHA0717 562203.0 8494213.0 1176.7 HA 8 23/07/2025 EL0492
RGHA0718 563009.0 8494222.0 1182.2 HA 10 23/07/2025 EL0492
RGHA0719 563263.7 8494999.0 1180.8 HA 4 23/07/2025 EL0492
RGHA0720 564002.4 8495002.1 1194.3 HA 12 24/07/2025 EL0492
RGHA0721 564802.0 8495011.1 1214.7 HA 12 24/07/2025 EL0492
RGHA0722 564597.0 8497398.1 1207.1 HA 7 24/07/2025 EL0492
RGHA0723 565398.0 8497404.0 1216.0 HA 12 24/07/2025 EL0492
RRHA0001 539105.6 8462750.9 1137.5 HA 3 17/08/2019 EL0609
RRHA0002 538904.1 8462692.5 1135.6 HA 15 17/08/2019 EL0609
RRHA0003 538717.4 8462609.0 1133.7 HA 17 19/08/2019 EL0609
RRHA0004 538554.7 8462498.0 1132.5 HA 16 19/08/2019 EL0609
RRHA0005 538400.3 8462351.7 1131.0 HA 12 19/08/2019 EL0609
RRHA0006 538253.4 8462197.5 1128.9 HA 11 19/08/2019 EL0609
RRHA0007 538102.3 8462042.2 1126.7 HA 13 19/08/2019 EL0609
RRHA0008 537953.9 8461906.4 1124.9 HA 15 19/08/2019 EL0710
RRHA0009 537759.8 8461810.1 1122.7 HA 11 20/08/2019 EL0710
RRHA0010 539101.1 8462763.1 1137.5 HA 14 17/08/2019 EL0609
RRHA0013 538499.9 8462747.2 1130.7 HA 12 09/10/2019 EL0609
RRHA0017 537999.9 8462600.1 1125.1 HA 14 10/10/2019 EL0710
RRHA0018 538000.0 8462399.9 1126.0 HA 11 10/10/2019 EL0710
RRHA0019 537998.0 8462201.8 1125.9 HA 14 10/10/2019 EL0710
RRHA0020 538000.0 8462000.4 1125.6 HA 10 11/10/2019 EL0710
RRHA0021 537999.6 8461800.0 1124.5 HA 11 11/10/2019 EL0710
RRHA0022 538000.5 8461599.2 1122.3 HA 15 11/10/2019 EL0710
RRHA0025 538799.3 8462799.7 1134.1 HA 15 12/10/2019 EL0609
RRHA0033 537200.2 8461799.8 1117.1 HA 10 13/10/2019 EL0710
RRHA0034 537200.0 8462200.0 1112.0 HA 2 20/10/2019 EL0710
RRHA0040 538400.1 8462799.9 1128.8 HA 13 21/10/2019 EL0609
RRHA0041 538400.0 8462600.0 1130.4 HA 10 21/10/2019 EL0609
RRHA0052 537800.0 8462300.0 1123.1 HA 10 24/10/2019 EL0710
RRHA0053 537800.1 8462099.9 1123.5 HA 13 24/10/2019 EL0710
RRHA0054 537800.1 8461900.0 1123.5 HA 15 24/10/2019 EL0710
RRHA0055 537799.8 8461699.9 1122.3 HA 14 24/10/2019 EL0710
RRHA0056 537799.8 8461500.1 1120.1 HA 13 24/10/2019 EL0710
RRHA0057 538199.7 8462500.3 1128.1 HA 12 25/10/2019 EL0609
RRHA0058 538200.1 8462300.1 1128.5 HA 13 25/10/2019 EL0609
RRHA0059 538196.8 8462105.2 1128.0 HA 15 25/10/2019 EL0609
RRHA0060 538199.8 8461900.0 1126.5 HA 9 25/10/2019 EL0710
RRHA0061 538199.9 8461700.0 1124.5 HA 11 25/10/2019 EL0710
This information is provided by RNS, the news service of the London Stock Exchange. RNS is approved by the Financial Conduct Authority to act as a Primary Information Provider in the United Kingdom. Terms and conditions relating to the use and distribution of this information may apply. For further information, please contact
rns@lseg.com (mailto:rns@lseg.com)
or visit
www.rns.com (http://www.rns.com/)
.
RNS may use your IP address to confirm compliance with the terms and conditions, to analyse how you engage with the information contained in this communication, and to share such analysis on an anonymised basis with others as part of our commercial services. For further information about how RNS and the London Stock Exchange use the personal data you provide us, please see our
Privacy Policy (https://www.lseg.com/privacy-and-cookie-policy)
. END DRLGXGDXLBBDGLI
Copyright 2019 Regulatory News Service, all rights reservedRecent news on Sovereign Metals
See all newsREG - Sovereign Metals Ltd - Kasiya MRE Significantly Upgraded Ahead of DFS
AnnouncementREG - Sovereign Metals Ltd - Sovereign Signs Rutile Offtake MoU with Mitsui
AnnouncementREG - Sovereign Metals Ltd - Half Year Accounts
AnnouncementREG - Sovereign Metals Ltd - Results of Meeting
AnnouncementREG - Sovereign Metals Ltd - Issue of Performance Rights
Announcement