The rise in demand for chrome has been driven in great part by the China-dominated stainless steel industry, which represents more than 75% of chromium consumption. South Africa is a dominant global supplier of chrome ore and ferrochrome, and the biggest exporter to China – in 2017, it accounted for 73% of the country’s chrome imports.
South African chrome mining operations have been facing the challenge of meeting this rising demand while dealing with electricity and price constraints. They have been expanding into larger-scale underground and open-cut operations. These higher-capacity, less selective mining processes produce greater amounts of marginal or lower grade material due to the dilution of the main ore body.
This translates into higher costs, as the traditional methods for separating this low-chromite content material, such as dense media separation, cyclones and spirals, are power and water-intensive or require costly agents.
TOMRA’s x-ray transmission (XRT) sensor-based ore sorting is a technology in physical separation that has proved effective in mining operations for a variety of minerals, including chrome. Its benefits include: less complexity in the process, lower costs, higher productivity and profitability and a lower environmental impact.
The x-ray sensor accurately establishes the density of each particle in the feed, and high-speed pneumatic ejectors separate ore with high chromite content from bare or low-grade ore at throughputs between 60 and 200 tph. The resulting output is a high-grade product that is ready to sell, with no need for additional comminution. It is a dry process that requires no water or reagents, and is frugal in its energy consumption, resulting in a fraction of the capital expenditure and running costs of traditional methods, as well as a smaller footprint.
TOMRA’s XRT technology used in LG6 mine
Engineering and project management company P2E Consulting has implemented TOMRA’s XRT technology in sorting chrome ore at Eastern Chrome mines in South Africa. They were looking for a solution to improve the efficiency of the sorting plant: “We have installed TOMRA sorters on diamond and copper plants in the past and we believe their technology is ahead of their competitors,” states Craig Meadway, Business Development Executive of P2E Consulting.
P2E Consulting commissioned a TOMRA COM XRT 2.0 sorter to replace an existing drum Dense Media Separation (DMS) plant: “The mine used the DMS plant to produce saleable small lumpy product from the mine’s LG6 Chromite ROM and dumps at a minimum grade of 38%, but it was very inefficient,” explains Craig Meadway. “The TOMRA XRT sorter has resolved this issue. It is used to upgrade under value material with a head grade of 20% - 28%, to produce a saleable product at a minimum grade of 38% Cr2O3. It does this efficiently and at a low cost of production.”
The XRT 2.0 sorter has achieved grades in excess of 40% Cr2O3 and mass recoveries of 25 - 30% from scalped waste, resulting in chrome-in-tails as low as 12%: “No other technology has given us such a high recovery rate. Not only that, with TOMRA’s XRT there was no water usage at all and we did not need to spend on expensive reagents, so that we are producing small lumpy product for approximately 50% of the cost compared to a DMS plant.”
The environmental benefits of the company’s XRT solution were also an important factor in P2E Consulting’s choice of technology: “We are looking to introduce greener technologies into the mining industry. The fact that no water or chemicals are used is a major advantage,” adds Meadway. “Also, South Africa has major power limitations, and the lower energy consumption when compared to DMS is a huge driving force.”
The easy operation of TOMRA’s XRT sorters is a further advantage: “It is very easy to use: once the sorter and feed system control philosophy is set up correctly, the plant runs with very little input from the operators,” explains Meadway.
Read the article online at: https://www.globalminingreview.com/mining/17032020/tomras-uses-xrt-sorting-on-lumpy-chrome-ore/