Maptek’s Vulcan software is helping one savvy Greek quarries manager accurately plan and manage his marble reserves. Guy Woodford reports in our sister title Aggregates Business.
The English idiom ‘It’s all Greek to me’ refers to something that is difficult to understand. How best to secure accurate mineral reserves data and find the right platform to clearly interpret it can fit such a turn of phrase, but one Greek quarrying company believes it has found the answer in the form of Maptek’s Vulcan software.
Iktinos Hellas SA and its quarries manager Charalambos Almbanopoulos is using Vulcan at the company’s Platanotopos marble quarry in north-eastern Greece for resource and reserve estimation using quality indicators.
The use of standard estimation and modelling software tools in estimating marble quarry reserves poses several challenges. Reserves are based on marble quality categories which are unique for each deposit. These categories represent visual and physical aspects such as colour, texture and fractures.
Classification is performed by experienced personnel and is based on much smaller samples than the slabs of marble produced. Furthermore, the available information is mostly qualitative, leading to further complications in the application of geomathematical estimation methods.
Almbanopoulos and Iktinos Hellas SA use Maptek Vulcan in the estimation of Platanotopos quarry’s marble reserves based on interpolating quality indicator values from drill hole and quarry face samples to 3D blocks.
Located in public forest land and at an elevation of 380m–540m above sea level, Platanotopos quarry contains calcitic marbles, gneiss and gneissic schists which have no commercial value and are not exploited. Interest is focused on dolomitic marbles, which occur as lenses enclosed by alternating gneissic schist layers and calcitic marbles.
The marble-bearing horizon has a regular strike, with dips between 25° and 30°. The lensoid dolomitic microcrystalline marbles are massive, white, fine-grained and traversed by red-yellow ‘spider-web’ fractures filled with secondary iron oxides and hydroxides. Because the marbles are massive, large slabs can be recovered with minimal production of waste material. The weathered top 1–2 m of the deposit has a low recovery factor for marketable marble.
Quarry production is scheduled for 7,000–10,000m³/year, with an estimated operation life of 15 years. The marble, known as ‘Golden Spider’, has very good physical and mechanical properties and can take a very high polish.
The blocks from the Platanotopos quarry are 6 × 2.8 × 7 m. Quality grading is initially based on colour: gold, yellow or red. Further grading categorises the different spider-web textures. Each block is then classified based on defects such as fractures, dendrite zones, brown lines, discolourings or marks, and a final quality is assigned according to a combination of grading types.
Data used in the resources and reserves estimation includes the original and current topography, as well as diamond drill hole samples and sections on quarry faces which are analysed every metre as to the marble quality.
A total of 1684 one-metre samples, from 47 sections and 45 drill holes, were used in reserve estimation. The data covered the extent of the estimated final pit and was validated in Vulcan for collar location and overlapping intervals.
The estimated volume of the final excavation was designed per bench (level) starting from the existing quarry morphology. The design of each of the 16 benches was modelled as a solid triangulation. These solids were visually checked and validated using triangulation topology checks (self-crossing, opening, inconsistencies) to ensure suitability for volumetric calculations.
The drill hole and section sample database was configured with extra fields (indicators) to allow the interpolation of arithmetic values. Specifically, fields were added representing the different marble qualities based on original colour, texture, fracture and tectonism.
Tectonism is handled separately because the different orientations of large-scale tectonism require a different search ellipsoid orientation. This is combined with initial qualities to derive the final quality classifications, with downgrading as necessary based on the estimated value of this field.
After calculation of initial quality and tectonism categories, the location of each sample is calculated, and a weighting factor is assigned. More weight is given to face sections as quality assessment is performed on a surface larger than the drill core and therefore better approaches the actual quality in that location. Weighting factors are used to further assess samples during interpolation.
Quality-class field values were interpolated using the inverse distance-squared method as implemented in a Vulcan block model. The estimated volume is divided into blocks of the same size. Block dimensions were configured based on the marble volumes extracted separately at the Platanotopos quarry.
In each block, the percentage of each marble quality was estimated using neighbouring samples. These samples are selected around each block using search ellipsoids oriented according to the geological features of the deposit. A special Vulcan function was used to calculate the appropriate ellipsoid orientation for each block, taking into account reference surfaces that define folding.
Generalisation of qualities was considered necessary as the limited sampling does not allow for a more detailed analysis of reserves to the original quality categories produced by the quarry. Reported waste quantities are the remaining bench volumes, which cannot be estimated using the available sampling and the limitations set by the reserve categories.
A considerable part of the waste and the inferred resources can potentially be upgraded in the future with additional drilling, which will provide a clearer and more detailed picture in areas where there are currently no samples.
This method gives Iktinos Hellas SA reliable results according to international standards of resources/reserves reporting. Future work will include integration of historical production data with the quality estimation process and implementation of an appropriate production quality-control system that will produce the necessary data to improve the current quality models and reserve classification.
Speaking about the benefits of Maptek’s Vulcan software, Charalambos Almbanopoulos says: “Having a systematic procedure for reserves calculation and the ability to visualise quarry plans and estimated qualities in three dimensions are the main benefits of using Maptek Vulcan QuarryModeller.”
Speaking about what specific features he most likes about the Maptek software solution, he adds: “The ability of the software to configure and adjust sample database structures and standard estimation procedures so that they can be used to estimate categorical marble qualities.”