ETD Collection

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Author: search.filters.author.Chanderman, LisaHas files: Yes

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    Application of stochastic orebody simulation techniques to assess geological volume and grade uncertainty for gold reef deposits
    (2017) Chanderman, Lisa
    This dissertation discusses the use of stochastic orebody modelling techniques for assessing geological uncertainty associated with gold mineralisation at Geita Gold Mine in Tanzania, and proposes a practical methodology that can be applied to similar studies. As part of the pre-feasibility stage studies for underground mining at Geita, stochastic simulations were required to assess the geological uncertainty associated with isolating (modelled) high grade lenses that occur within the known low grade mineralisation currently targeted for underground mining. Two different simulation techniques are applied in this research: Sequential Indicator Simulation to generate lithofacies realisations from which to assess ore category boundaries and shapes for use in quantifying volumetric uncertainty; and Direct Block Simulations to simulate gold grade realisations from which to assess grade uncertainty. This study identified potential upside and downside mine planning scenarios for volumes and total metal content from the ore category and grade simulations respectively. The findings of the results demonstrated that the high grade zones are much more broken up and discontinuous than the currently modelled high grade shape. The current business case uses a probabilistic high grade shape based on a single grade indicator and a probability choice of 50 percent as the threshold for high grade. The results of the study consider a simulation of possible outcomes based on the same threshold grade indicator and hence quantify the uncertainty or total geological risk. This geological risk may be introduced to mine designs, production schedules and NPV predictions The stochastic workflow developed can be applied to analogous deposit types to assess the risk related to geological uncertainty. The work includes a description of practical considerations to be accounted for when applying the techniques.
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    3D geological modelling and mineral resource estimate for the FE2 gold deposit, Sadiola mine, Mali
    (2016-04-05) Chanderman, Lisa
    The FE2 Gold Deposit forms part of Sadiola Mine located in south-western Mali - nearby the border with Senegal - approximately 440km north-west of the capital Bamako, and 70km south of the city of Kayes. Sadiola Mine is made up of 7 open pits (the Main Pit, FN3, FE2, FE3, FE4, Tambali and Sekokoto). Gold (Au) mineralisation is spatially associated with a complex alteration pattern, pointing to a mesothermal origin for the Au mineralisation. The Main Pit deposit contains an Oxide portion and a deeper Sulphide zone comprised of unweathered material below the pit. In 2010, mining of the Oxide portion was concluded. Currently, Sadiola does not have the plant capability to treat Sulphides due to its hardness and most of the Oxide Mineral Reserve in the concession has been depleted. The FE2 deposit is expected to provide Oxide Ore for 7 months based on the current mine plan. The Oxide mining on the Sadiola concession has an expected life of 3 years. Sadiola’s future is thus tied to the fate of the Sadiola Sulphides Project (SSP), targeted at exploiting the Sulphide zone Ore. In the absence the SSP materialising to date, focus has shifted to the FE2 deposit to scavenge any remaining Oxide Ore, to prolong mine life. The previous Mineral Resource model was generated in June 2014. The model was based on grade control drilling information. The current Mineral Resource Estimate (MRE), presented in this research report, was prompted by an Advanced Grade Control (AGC) drilling campaign that took place during October 2014 to identify additional Oxide Ore Mineral Resource (Indicated, Inferred and Blue Sky Potential). The AGC drillholes (12.5m (X) by 12.5m (Y) drill spacing) have been drilled mostly as infill drilling and all holes had accompanying assay data. The Ore and Graphite mesh modelling was conducted using the grade interpolation technique in Leapfrog® mining software. The Hardness, Redox, Laterite and Classification wireframes were created in Datamine® Studio 3 software. A lower geological cut-off of 0.32g/t Au was applied to the mineralised domains. Three domains were estimated: EZONE 1 (Laterite and Saprolite Ore); EZONE 2 (Hard Ore i.e. Sulphides) and EZONE 3 (Waste). All estimation into the Mineral Resource model was done in Datamine® Studio 3. Ordinary Kriging (OK) was used to estimate the Au grades; Inverse Power of Distance (IPD) to estimate “hardness probabilities” for isolated hard/blastable material above the hard/soft contact; and Indicator Kriging (IK) used to estimate the distribution of the Graphitic alteration. The Au estimation process was optimised using Quantitative Kriging Neighbourhood Analysis (QKNA). The estimates were validated visually, statistically and using swath analyses. Uniform Conditioning (UC) was used to estimate the recoverable Mineral Resource in EZONES 1 and 2 for the reporting of the distribution of grades above various economic cut-offs. The Selective Mining Unit (SMU) size assumed for the FE2 UC process was 10m (X) x 10m (Y) x 3.33m (Z) and was based on the selectivity achievable with the current mining equipment. Given the panel size of 25m (X) x 25m (Y) x 10m (Z), there were about 18 SMUs in each panel. A tonnage adjustment factor was applied and was based on a volume representing half the SMU size. It was expressed as a percentage of the panel size (2.7%). Any proportions smaller than this percentage were removed as they would not be practically recoverable (these volumes would be too small to mine with the selected equipment). The Mineral Resource was classified in accordance with the South African Code for Reporting of Exploration Results, Mineral Resources and Mineral Reserves (SAMREC) and the Australian Joint Ore Reserves Committee (JORC) guidelines. A drill spacing of 25m (X) by 25m (Y) was considered sufficient to classify the Mineral Resource as Indicated, and 50m (X) by 50m (Y) as Inferred. Areas covered by larger drill spacing were considered to be Blue Sky Potential (not an official Mineral Resource Category, but used for internal purposes by AngloGold Ashanti Limited (AGA) to estimate possible mineralisation potential). No Measured Mineral Resource was defined. The classification criteria are based on studies completed for other, similar Sadiola deposits (such as FE3 and FE4). The 2014 Mineral Resource model was compared with the updated Mineral Resource model (2015) within a common volume i.e. within the Business Plan (BP) 2015 $1,600 Mineral Resource shell and the $1,200 Mineral Reserve design (below the topography as no mining has taken place at FE2) to quantify if the Oxide Ore potential had increased as a result of the model update (Table 1). The detailed Reconciliation study showed that the new estimate identified an additional 7,191 ounces of Indicated Mineral Resource – of which, 1,893 ounces was previously classified as Inferred Mineral Resource but was upgraded to the Indicated Mineral Resource category as a result of the new Mineral Resource model. The reason for the increase is due to the new drilling results which resulted in the extension of some of the mineralised zones and showed better continuity for others. Table 1:Model reconciliation by broader material types: 2014 vs. 2015 MW cut-off grades.A checklist of assessment and reporting criteria based on the JORC code showed that no major risks to the model exist. However, some key recommendations were made and include: - Testing domaining and variography at various geological cut-offs - Performing an updated Classification study to confirm the suitability of the Classification criteria used - Soft Oxide density probe measurements reported in 2015 were significantly higher than in 2014. Further work needs to be done to confirm the validity of the density results before updating the 2015 density values - Testing estimation software used in the estimation process against similar software in the industry to single out the one that provides the most accurate results - Further work should be carried out to assess the effect of top cuts and top caps on the resulting Mineral Resource models - Further work is required on boundary analysis going forward as in reality the Laterite and Saprolite are very different, despite the results of the statistics suggesting that they are similar. - The latest LIDAR survey had not been provided at the time of Ore wireframe modelling. A new survey needs to be carried out to ensure that drillholes collar positions used in the modelling were correct - Further work is required to understand what method is best to model the extent of the graphitic alteration and how to optimise the method