Modern mining and technology

By | 08.01.2018
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The MMTS committee will be setting up a Modern Mining & Technology Sudbury Awareness booth during this event to promote our upcoming Modern Mining & Technology Week. Modern Mining & Technology Sudbury. 932 likes. The goal of Modern Mining & Technology Sudbury is to promote the many rewarding careers available in. If you received the latest edition of Modern Mining And Technology Sudbury Magazine (published by Sudbury Living) you will see one of my recent images of Lance.
The mining and industrial workplace has continued to undergo a transformation during the last 12 months as technology plays an ever more crucial role both in employee. A magazine that provides modern insight towards the mining sector and provides intensive research on Modern Mining Projects and technology in South Africa. The MMTS committee will be setting up a Modern Mining & Technology Sudbury Awareness booth during this event to promote our upcoming Modern Mining & Technology Week. Modern Mining & Technology Sudbury. 932 likes. The goal of Modern Mining & Technology Sudbury is to promote the many rewarding careers available in. If you received the latest edition of Modern Mining And Technology Sudbury Magazine (published by Sudbury Living) you will see one of my recent images of Lance.

10:30 AM: Dominic Fragomeni, P.Eng.
Company:  XPS Consulting & Testwork Services, A Glencore Company  

Topic: The Role of Quality Technical Expertise in Metallurgical Plant Design and Operations. Where did our technical horsepower go??
Professional engineer with over 27 years experience in mineral processing plant production and cost management, modern mining and technology, maintenance management, process optimization, plant commissioning and flowsheet development. Led in various technical support, project management and operations management capacities in Au, Cu/Pb/Zn and Ni in 5 concentrators in 3 provinces.  Concentrator metallurgical and operations management experience at Hemlo Gold Mines Inc., Golden Giant Mine, Brunswick Mining, Kidd Creek Mines, modern mining and technology, Sudbury Integrated Ni Operations (Falconbridge Strathcona Mill), Raglan Mill, FTC Corporate R&D. Currently Director, XPS Consulting & Testwork Services, A Glencore Company. Accountable for business profitability, providing senior management and strategic direction to XPS. Graduate of the Haileybury Modern mining and technology of Mines (1984) and Queen's University (B. Sc Mining Engineering - Mineral Extraction Option 1988). Author of over 10 technical papers, Chairman Canadian Mineral Processors Division of CIM (2010) and a Fellow of the CIM (2011). XPS is an autonomous technology business within Glencore providing metallurgical testing and consulting with expertise in mineral processing, quantitative mineralogy, extractive metallurgy, process control and materials technology.  XPS is based in Sudbury, Ontario at the XPS Centre, a 6000 m2 laboratory and pilot plant facility and employs over 50 engineers, technologists and coal mining countries world providing services for clients from over 25 countries world-wide in base and precious metals, rare earths and chromite. Dominic will explore, The Role of Quality Technical Expertise in Metallurgical Plant Design and Operations. Where did our technical horsepower go??

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Leading magazine on Mining technology in South Africa

If you received the latest edition of Modern Mining And Technology Sudbury Magazine (published by Sudbury Living) you will see one of my recent images of Lance. Read chapter 3 Technologies in Exploration, Mining, Read chapter 3 Technologies in Exploration, Mining, and Processing: and modern technology for planning. Modern Coal Related Technology Complex surface mining equipment is used directly or as support in the mineral Mining Transportation & The Tools of Coal. MODERN MINING TECHNOLOGY CONFERENCE & LUNCHEON. Join us August 19th - 8 experts will be speaking on New Technology. Time & Topics have been posted below. MODERN MINING TECHNOLOGY FOR COAL EXTRACTION Chandrani Prasad Verma Dr. John Loui P Dr. N. R. Thote [email protected] Modern mining processes involve prospecting for ore bodies, their technology was essentially identical to their Bronze Age predecessors. At other mines.

Modern mining processes involve prospecting for ore bodies, their technology was essentially identical to their Bronze Age predecessors. At other mines. If you received the latest edition of Modern Mining And Technology Sudbury Magazine (published by Sudbury Living) you will see one of my recent images of Lance. Now on Sunday! This Showcase, located at the New Sudbury Centre, features mining and technology-related exhibits from businesses, government agencies.


Drilling and blasting methods are commonly used to excavate hardrock in both surface and underground mining. Blasting is also used to move large amounts of overburden (blast casting) in some surface mining operations. Improved blasting methods for more precise rock movement and better control of the fragment sizes would reduce the cost of overbreak removal, as well as the cost of downstream processing.

Recommended areas for research and development in cutting and fragmentation are the development of hardrock cutting methods and tools and improved blast designs. Research on the design of more mobile, rapid, and reliable hardrock excavation would benefit both the mining and underground construction industries. Early focus of this research should be on a better understanding of fracture mechanisms in rock so that better cutters can be designed (NRC, 1996b). In addition, preconditioning the rock with water jets, thermal impulses, explosive impulses, or other techniques are promising technologies for weakening rock, which would make subsequent mechanical cutting easier. Novel combinations of preconditioning and cutting should also be investigated. Numerous ideas for the rapid excavation of hard rock were explored in the early 1970s, motivated by the defense community. These concepts should be re-examined in light of technological improvements in the last 20 years that could make some of the concepts more feasible (Conroy et al., 2000).

Improvements in blast design (e.g., computer-simulation-assisted design) would improve perimeter control, casting, and control of fragment size and would result in large energy savings by decreasing the need for downstream crushing and grinding. New methods of explosive tailoring and timing would also have significant benefits. Research into novel applications of blasting technology for the preparation of in-situ rubble beds for processing would help overcome some of the major barriers to the development of large-scale, in-situ processing methods. New developments in micro-explosives that could be pumped into thin fractures and detonated should be explored for their applications to in-situ fracturing and increasing permeability for processing. These methods would also have applications for coal gasification and in-situ leaching.

The development of better and faster rock-cutting and fragmentation methods, especially for applications to hard rock and in-situ mining, would result in dramatic improvements in productivity and would have some ancillary health and environmental risks and benefits. Mechanized, continuous mining operations are recognized as inherently safer than conventional drill-and-blast mining because it requires fewer unit operations, enables faster installation of ground support, and exposes fewer personnel to hazards. Continuous mining methods for underground hard-rock mining would also raise the level of productivity considerably. The environmental risks associated with in-situ mine-bed preparation by injection of explosives or other means of creating permeability will have to be evaluated. This evaluation should include the hazardous effects of unexploded materials or poisonous by-products in the case of chemical generation of permeability. Current thinking is that these risks would not be high relative to the risks of the processing operations used in in-situ mineral extraction (e.g., retorting and leaching).

Ground Control

The planning and design of virtually all elements of a mining system—openings, roadways, pillars, supports, mining method, sequence of extraction, and equipment—are dictated by the geological and geotechnical characterization of the mine site. The objective of ground control is to use site information and the principles of rock mechanics to engineer mine structures for designed purposes. Massive failures of pillars in underground mines, severe coal and rock bursts, open-pit slope failures, and roof and side falls all represent unexpected failures of the system to meet its design standard. These failures often result in loss of lives, equipment, and in some cases large portions of the reserves. Mining-related environmental problems, such as subsidence, slope instability, and impoundment failures, also reflect the need for more attention to the long-term effects of ground control on mine closures and facility construction.

Advances in numerical modeling, seismic monitoring, acoustic tomography, and rock-mass characterization have contributed immensely to the evolution of modern, ground-control design practices. Problems in mine design and rock engineering are complicated by the difficulties of characterizing rock and rock-mass behavior, inhomogenity and anisotropy, fractures, in-situ stresses, induced stress, and groundwater. The increasing scale of mining operations and equipment, coupled with the greater depths of mining and higher extraction rates, will require improved procedures for ground-control design and monitoring and improved prediction systems for operational ground control.

Site-characterization methods for determining the distributions of intact rock properties and the collective properties of the rock mass will require further development of geostatistical methods and their incorporation into design methodologies for ground support (NRC, 1995b). So far, automated monitoring data, such as data from seismic and/or other geophysical monitoring networks, have not been successfully integrated into the design of mine structures. In addition, ground-support elements, such as rock bolts, could be installed at selected locations and instrumented to monitor stress, support loads, and conditions (to determine maintenance intervals) to validate ground-support designs. With rapid advances in mathematics and numerical modeling, research should focus on approaches, such as real-time analysis and interrogation of data with three-dimensional models. In addition, the heterogeneity of rock strata and the diverse processes acting on the mine system (e.g., geologic, hydrologic, mechanical, and engineering processes) should

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