The document discusses safety issues in artisanal surface mining operations. It identifies the top causes of accidents as rockfalls, lack of ventilation, misuse of explosives, lack of training, and poor equipment. It recommends bench mining with terraced steps to improve stability and prevent rocks from falling. Other safety recommendations include using protective equipment, training programs, establishing medical facilities, and introducing alternative equipment when feasible. The goal is to improve conditions and raise awareness of risks in a practical way appropriate to local contexts and resources.
There are two broad categories of coal mines in India: open cast and underground mines. Accidents commonly occur from roof or side falls, winding machinery, haulage, dumpers, conveyors, other transport machinery, explosives, electricity, dust or gas inhalation, and falling objects. Recommendations to reduce mining accidents include improving communications systems, self-rescue equipment, emergency response, and introducing new mining technologies and safety monitoring systems.
1. The document discusses caught-between hazards and solutions to mitigate them. It provides examples of common caught-between hazards like moving pipe, tongs, mobile equipment, and unguarded machine parts.
2. Corrective actions are suggested to avoid caught-between injuries, including using tag lines and push/pull poles to maneuver loads from a safe distance, keeping hands clear of hazards while equipment is moving, and ensuring proper machine guarding.
3. The manufacturer Project Sales Corp provides safety tools like tangle-resistant tag lines, load guiders, and push/pull poles to facilitate hands-free operation and prevent workers from being caught between objects.
This document provides an overview of caught-in or between hazards in construction. It discusses what caught-in hazards are, common types seen in construction like machinery with unguarded parts, trench collapses, and being pinned between objects. Statistics on caught-in injuries and fatalities are presented. The document also outlines how workers can protect themselves, such as using proper guards, lockout procedures, and trench protections. Finally, it discusses employer requirements to prevent caught-in hazards through guards, lockout compliance, fall protections, trench safety systems, and training.
Trench Safety Month is June! Trenching and excavation training should be provided to employees in order to comply with OSHA regulations and to learn about trenching hazards and how to reduce them.
This document discusses several conveyor and crusher-related accidents at mining operations and provides best practices to improve safety. It summarizes accidents where workers were caught in moving machinery while performing maintenance or cleaning near unguarded parts of conveyors and crushers that were still in operation. The best practices emphasize locking out power sources, using guards on all moving parts, ensuring proper training for all tasks, and conducting risk assessments before performing any work near heavy equipment.
This chapter provides an overview of surface mining methods and equipment. Section 1 describes various surface mining methods including open pit mining, open cast mining, placer mining, and solution mining. Open pit and open cast mining use mechanical excavation in a dry environment, while placer and solution mining use water or chemical solutions. Section 2 briefly discusses large surface mining machinery such as bucket wheel excavators, shovels, and draglines. The chapter compares advantages and disadvantages of surface and underground mining, noting that surface mining typically has higher productivity and lower costs but can cause more environmental impacts.
There are two broad categories of coal mines in India: open cast and underground mines. Accidents commonly occur from roof or side falls, winding machinery, haulage, dumpers, conveyors, other transport machinery, explosives, electricity, dust or gas inhalation, and falling objects. Recommendations to reduce mining accidents include improving communications systems, self-rescue equipment, emergency response, and introducing new mining technologies and safety monitoring systems.
1. The document discusses caught-between hazards and solutions to mitigate them. It provides examples of common caught-between hazards like moving pipe, tongs, mobile equipment, and unguarded machine parts.
2. Corrective actions are suggested to avoid caught-between injuries, including using tag lines and push/pull poles to maneuver loads from a safe distance, keeping hands clear of hazards while equipment is moving, and ensuring proper machine guarding.
3. The manufacturer Project Sales Corp provides safety tools like tangle-resistant tag lines, load guiders, and push/pull poles to facilitate hands-free operation and prevent workers from being caught between objects.
This document provides an overview of caught-in or between hazards in construction. It discusses what caught-in hazards are, common types seen in construction like machinery with unguarded parts, trench collapses, and being pinned between objects. Statistics on caught-in injuries and fatalities are presented. The document also outlines how workers can protect themselves, such as using proper guards, lockout procedures, and trench protections. Finally, it discusses employer requirements to prevent caught-in hazards through guards, lockout compliance, fall protections, trench safety systems, and training.
Trench Safety Month is June! Trenching and excavation training should be provided to employees in order to comply with OSHA regulations and to learn about trenching hazards and how to reduce them.
This document discusses several conveyor and crusher-related accidents at mining operations and provides best practices to improve safety. It summarizes accidents where workers were caught in moving machinery while performing maintenance or cleaning near unguarded parts of conveyors and crushers that were still in operation. The best practices emphasize locking out power sources, using guards on all moving parts, ensuring proper training for all tasks, and conducting risk assessments before performing any work near heavy equipment.
This chapter provides an overview of surface mining methods and equipment. Section 1 describes various surface mining methods including open pit mining, open cast mining, placer mining, and solution mining. Open pit and open cast mining use mechanical excavation in a dry environment, while placer and solution mining use water or chemical solutions. Section 2 briefly discusses large surface mining machinery such as bucket wheel excavators, shovels, and draglines. The chapter compares advantages and disadvantages of surface and underground mining, noting that surface mining typically has higher productivity and lower costs but can cause more environmental impacts.
1) The document discusses artisanal and small-scale gold mining (ASM), which provides livelihoods for many but also causes environmental degradation. Mercury amalgamation is commonly used to extract gold, releasing mercury that harms health and environment.
2) For new technologies to be adopted by ASM miners, they must be simple, recover gold quickly, and provide clear financial benefits. Factors like material availability and costs also influence acceptance.
3) The document reviews technologies, processing centers, formalization efforts, and how ASM can contribute to sustainable development through livelihood diversification. Appropriate application depends on the diversity of ASM communities worldwide.
The document discusses mining safety hazards and accidents in India. It notes that mining involves risks like cave-ins, rock falls, gas explosions, fires, and machinery accidents. Common causes of accidents include lack of proper roof support, unstable slopes, and build-up of flammable gases. To improve safety, the government established DGMS to inspect mines and promote safety programs. Ongoing efforts include better roof support systems, ventilation, fire suppression, and training workers to reduce accidents in the hazardous mining industry.
This document provides information on trench and excavation safety. It defines excavation and trenching, and outlines various safety methods like sloping, benching, shoring and shielding based on soil type. It discusses hazards like cave-ins, underground utilities, hazardous atmospheres, and recommends practices like atmospheric testing, protective systems, and inspections to ensure worker safety during excavation work.
Construction Safety Training_Session 02_Excavation Works, Hazards and Controls Muizz Anibire
Learning objectives
Identify the various types of hazards in excavation works.
Describe the planning process for excavation works.
Describe basic excavation support systems.
Identify excavation control measures and precautions.
EXCAVATION AND PREVENTION OF HAZARDS.pptxEricShawd
Excavation refers to a man-made cut, trench, or depression created by earth removal.
Excavation is an integral part of many construction projects, including building foundations and public infrastructure projects like building roads.
Excavation sites present numerous hazards that can lead to serious injuries and death.
The major hazards include trench collapses, falls, falling objects, hazardous atmospheres, mobile equipment accidents, electrical hazards, and inclement weather.
This presentation aims to raise awareness about the hazards associated with excavation work and provide control measures to prevent accidents and ensure a safe working environment.
This document discusses trends in underground mining methods. It notes that investments in new mines have increased dramatically in recent years and are expected to remain high. Global metal production has increased steadily each year to around 5,000 million tonnes annually, with 17% coming from underground mines. Underground mining techniques have advanced rapidly in recent decades through mechanization, allowing for larger volumes of rock to be excavated safely and efficiently. Contractors now play a larger role in underground development and infrastructure works.
What is a Stope In Mining: Uncovering the Hidden Treasures of Ore DepositsHetherington
Explore the significance of this underground excavation in extracting precious ore deposits. Learn about the methods, challenges, and the crucial role stopes play in the mining industry. Unlock the hidden treasures beneath the surface with our comprehensive guide.
This document discusses drilling and production operations in the petroleum industry. It describes the current drilling techniques used, which involve using rigs to rotate drill bits and circulate drilling muds. Problems with current drilling methods include downtime from dull bits and formation fluid leakage. The document also discusses the components and environmental impacts of drilling muds. It then summarizes the typical components and process of offshore production facilities, using the Sable Island gas project as an example. The project involves multiple unmanned satellite platforms connected to a central manned complex.
The document discusses the benefits of mechanizing mining operations to improve safety standards and phase out manual loading. It provides statistics showing a reduction in accidents, especially those due to roof and side falls, after mechanization was introduced at mines operated by SCCL in India. Mechanization led to a 50% reduction in fatalities and allowed experienced workers to be redeployed to safer roles. However, additional safety precautions are needed to address new risks from increased electricity, moving machinery, and equipment maintenance.
NIOSH - Preventing Worker Deaths from Trench Cave-ins Robson Peixoto
Workers performing excavation and trenching are at high risk of fatal injury from cave-ins. From 2000-2009, an average of 35 workers died each year in trench cave-ins. Proper protective systems such as sloping, shoring, or trench boxes are required but are often not used. Two case studies describe incidents where Hispanic laborers working in unprotected trenches were fully buried and suffocated when the walls collapsed. NIOSH recommends pre-job planning, competent oversight, protective systems, training, and safe work practices to prevent the life-threatening hazards of trench cave-ins.
Construction Safety Training_Session 04_Working at Heights and Over WaterMuizz Anibire
Learning Objectives
Identify typical construction activities the require work at heights
Identify the various types of hazards and their control measures in working at heights
Describe work at height access equipment
Describe safety controls and precautions for work at height access equipment
International Journal of Computational Engineering Research (IJCER) ijceronline
International Journal of Computational Engineering Research(IJCER) is an intentional online Journal in English monthly publishing journal. This Journal publish original research work that contributes significantly to further the scientific knowledge in engineering and Technology
In mining operations, blasting has become a routine work. With proper understanding of the rocks and blasting methods, the mining work can be done effectively. This module explains the rock blasting methods adopted in mining industries.
The document provides background information on Syferfontein Dolomite Mine located in South Africa. It describes the mine's location, vegetation, topography, climate, equipment used, mining processes including drilling, blasting, excavation, loading, haulage and processing. It discusses the mine's products and their uses. Safety and health measures are also outlined. In conclusion, recommendations are made regarding production exploration, mine design planning, and machinery investment to improve efficiency.
This document provides an overview of oil well drilling methods, challenges, and future trends. It discusses conventional vertical drilling as well as techniques like directional, hydraulic fracturing, and offshore drilling. Maintaining well integrity and controlling pressures are ongoing challenges, while automation, digitalization, and renewable energy integration may drive future improvements in sustainability. Environmental impacts, technological difficulties, and safety risks associated with drilling must also be managed carefully.
This document provides an overview of oil well drilling methods, challenges, and future trends. It discusses conventional vertical drilling as well as techniques like directional, hydraulic fracturing, and offshore drilling. Maintaining well integrity and controlling pressures are ongoing challenges, while automation, digitalization, and renewable energy integration may drive future improvements in sustainability. Oil drilling balances energy production with environmental protection through continued innovation.
We can help you to maximize ore reserve value basis on our operating expertise .
We have years of underground mine engineering and operating experience and across multiple commodities using all common mining methods.
Especially, we have many successful design and operation experiences for underground coal mines those are thin coal seam, large dip angle, as well as many faultags. And most of these coal mines (thin coal seam) are designed and operated by longwall mining method (fully mechanized mining). The thin coal seam longwall method helps to satisfy the highest safety standard and more margins.
Large dip angle, thin coal seam longwall (dip angle range: 35°-55°)
Thin coal seam, very thin coal seam longwall (Thinnest seam range: 0.8m ~ 1.3m)
Get in touch with us for more:
Sophie Guan | sophie.guan@alpha-technology.com.au
Importance of Proper Trench Shoring - James River LaserJames River Laser
Trench shoring is an essential practice in the construction industry that ensures the safety of workers involved in excavation projects. It involves implementing protective systems to prevent soil collapse and other hazards associated with working in trenches. In this section, we will explore the fundamentals of trench shoring and delve into the importance of excavation safety.
This document summarizes research on reducing oil shale losses during mining operations in Estonia. It finds that oil shale utilization losses can reach up to 70% depending on the mine and methods used. The researchers analyzed various extraction, crushing, separation and processing methods used in Estonia's oil shale mines. These included selective blasting, longwall mining, surface mining, mechanical shovel extraction, and fine separation technologies. Test results showed that surface miners can achieve productivities over 500 tonnes per hour with cutting speeds around 0.05-0.12 meters per second. Overall losses were highest (over 30%) in the deepest underground mine due to weak rock layers and increased depth. The researchers aim to further reduce losses through optimizing
1) The document discusses artisanal and small-scale gold mining (ASM), which provides livelihoods for many but also causes environmental degradation. Mercury amalgamation is commonly used to extract gold, releasing mercury that harms health and environment.
2) For new technologies to be adopted by ASM miners, they must be simple, recover gold quickly, and provide clear financial benefits. Factors like material availability and costs also influence acceptance.
3) The document reviews technologies, processing centers, formalization efforts, and how ASM can contribute to sustainable development through livelihood diversification. Appropriate application depends on the diversity of ASM communities worldwide.
The document discusses mining safety hazards and accidents in India. It notes that mining involves risks like cave-ins, rock falls, gas explosions, fires, and machinery accidents. Common causes of accidents include lack of proper roof support, unstable slopes, and build-up of flammable gases. To improve safety, the government established DGMS to inspect mines and promote safety programs. Ongoing efforts include better roof support systems, ventilation, fire suppression, and training workers to reduce accidents in the hazardous mining industry.
This document provides information on trench and excavation safety. It defines excavation and trenching, and outlines various safety methods like sloping, benching, shoring and shielding based on soil type. It discusses hazards like cave-ins, underground utilities, hazardous atmospheres, and recommends practices like atmospheric testing, protective systems, and inspections to ensure worker safety during excavation work.
Construction Safety Training_Session 02_Excavation Works, Hazards and Controls Muizz Anibire
Learning objectives
Identify the various types of hazards in excavation works.
Describe the planning process for excavation works.
Describe basic excavation support systems.
Identify excavation control measures and precautions.
EXCAVATION AND PREVENTION OF HAZARDS.pptxEricShawd
Excavation refers to a man-made cut, trench, or depression created by earth removal.
Excavation is an integral part of many construction projects, including building foundations and public infrastructure projects like building roads.
Excavation sites present numerous hazards that can lead to serious injuries and death.
The major hazards include trench collapses, falls, falling objects, hazardous atmospheres, mobile equipment accidents, electrical hazards, and inclement weather.
This presentation aims to raise awareness about the hazards associated with excavation work and provide control measures to prevent accidents and ensure a safe working environment.
This document discusses trends in underground mining methods. It notes that investments in new mines have increased dramatically in recent years and are expected to remain high. Global metal production has increased steadily each year to around 5,000 million tonnes annually, with 17% coming from underground mines. Underground mining techniques have advanced rapidly in recent decades through mechanization, allowing for larger volumes of rock to be excavated safely and efficiently. Contractors now play a larger role in underground development and infrastructure works.
What is a Stope In Mining: Uncovering the Hidden Treasures of Ore DepositsHetherington
Explore the significance of this underground excavation in extracting precious ore deposits. Learn about the methods, challenges, and the crucial role stopes play in the mining industry. Unlock the hidden treasures beneath the surface with our comprehensive guide.
This document discusses drilling and production operations in the petroleum industry. It describes the current drilling techniques used, which involve using rigs to rotate drill bits and circulate drilling muds. Problems with current drilling methods include downtime from dull bits and formation fluid leakage. The document also discusses the components and environmental impacts of drilling muds. It then summarizes the typical components and process of offshore production facilities, using the Sable Island gas project as an example. The project involves multiple unmanned satellite platforms connected to a central manned complex.
The document discusses the benefits of mechanizing mining operations to improve safety standards and phase out manual loading. It provides statistics showing a reduction in accidents, especially those due to roof and side falls, after mechanization was introduced at mines operated by SCCL in India. Mechanization led to a 50% reduction in fatalities and allowed experienced workers to be redeployed to safer roles. However, additional safety precautions are needed to address new risks from increased electricity, moving machinery, and equipment maintenance.
NIOSH - Preventing Worker Deaths from Trench Cave-ins Robson Peixoto
Workers performing excavation and trenching are at high risk of fatal injury from cave-ins. From 2000-2009, an average of 35 workers died each year in trench cave-ins. Proper protective systems such as sloping, shoring, or trench boxes are required but are often not used. Two case studies describe incidents where Hispanic laborers working in unprotected trenches were fully buried and suffocated when the walls collapsed. NIOSH recommends pre-job planning, competent oversight, protective systems, training, and safe work practices to prevent the life-threatening hazards of trench cave-ins.
Construction Safety Training_Session 04_Working at Heights and Over WaterMuizz Anibire
Learning Objectives
Identify typical construction activities the require work at heights
Identify the various types of hazards and their control measures in working at heights
Describe work at height access equipment
Describe safety controls and precautions for work at height access equipment
International Journal of Computational Engineering Research (IJCER) ijceronline
International Journal of Computational Engineering Research(IJCER) is an intentional online Journal in English monthly publishing journal. This Journal publish original research work that contributes significantly to further the scientific knowledge in engineering and Technology
In mining operations, blasting has become a routine work. With proper understanding of the rocks and blasting methods, the mining work can be done effectively. This module explains the rock blasting methods adopted in mining industries.
The document provides background information on Syferfontein Dolomite Mine located in South Africa. It describes the mine's location, vegetation, topography, climate, equipment used, mining processes including drilling, blasting, excavation, loading, haulage and processing. It discusses the mine's products and their uses. Safety and health measures are also outlined. In conclusion, recommendations are made regarding production exploration, mine design planning, and machinery investment to improve efficiency.
This document provides an overview of oil well drilling methods, challenges, and future trends. It discusses conventional vertical drilling as well as techniques like directional, hydraulic fracturing, and offshore drilling. Maintaining well integrity and controlling pressures are ongoing challenges, while automation, digitalization, and renewable energy integration may drive future improvements in sustainability. Environmental impacts, technological difficulties, and safety risks associated with drilling must also be managed carefully.
This document provides an overview of oil well drilling methods, challenges, and future trends. It discusses conventional vertical drilling as well as techniques like directional, hydraulic fracturing, and offshore drilling. Maintaining well integrity and controlling pressures are ongoing challenges, while automation, digitalization, and renewable energy integration may drive future improvements in sustainability. Oil drilling balances energy production with environmental protection through continued innovation.
We can help you to maximize ore reserve value basis on our operating expertise .
We have years of underground mine engineering and operating experience and across multiple commodities using all common mining methods.
Especially, we have many successful design and operation experiences for underground coal mines those are thin coal seam, large dip angle, as well as many faultags. And most of these coal mines (thin coal seam) are designed and operated by longwall mining method (fully mechanized mining). The thin coal seam longwall method helps to satisfy the highest safety standard and more margins.
Large dip angle, thin coal seam longwall (dip angle range: 35°-55°)
Thin coal seam, very thin coal seam longwall (Thinnest seam range: 0.8m ~ 1.3m)
Get in touch with us for more:
Sophie Guan | sophie.guan@alpha-technology.com.au
Importance of Proper Trench Shoring - James River LaserJames River Laser
Trench shoring is an essential practice in the construction industry that ensures the safety of workers involved in excavation projects. It involves implementing protective systems to prevent soil collapse and other hazards associated with working in trenches. In this section, we will explore the fundamentals of trench shoring and delve into the importance of excavation safety.
This document summarizes research on reducing oil shale losses during mining operations in Estonia. It finds that oil shale utilization losses can reach up to 70% depending on the mine and methods used. The researchers analyzed various extraction, crushing, separation and processing methods used in Estonia's oil shale mines. These included selective blasting, longwall mining, surface mining, mechanical shovel extraction, and fine separation technologies. Test results showed that surface miners can achieve productivities over 500 tonnes per hour with cutting speeds around 0.05-0.12 meters per second. Overall losses were highest (over 30%) in the deepest underground mine due to weak rock layers and increased depth. The researchers aim to further reduce losses through optimizing
1. The Southern African Institute of Mining and Metallurgy
Surface Mining 2014
S.M. Rupprecht
93
Safety aspects and recommendations for surface
artisanal mining
S.M. Rupprecht
University of Johannesburg
Artisanal mining is a significant industry in sub-Saharan Africa, accounting anywhere from
2% to 20% of a country’s gross domestic products (GDP). Safety concerns in artisanal
mining are often overlooked due to the nature of the business, which is largely a
subsistence occupation. This paper presents some of the risks commonly observed in
surface artisanal mining operations and provides basic safety recommendations for
operators to follow to prevent serious accidents or fatalities. The five most frequently cited
causes of serious accidents are rockfalls and collapses, lack of ventilation, misuse of
explosives, lack of knowledge and training, and obsolete and poorly maintained equipment.
Keywords: Surface mining safety, artisanal mining, small-scale mining
General nature of artisanal mining
The artisanal mining sector is largely informal, labour-intensive utilizing little or no machinery, yet provides an
essential livelihood (directly or indirectly) for many participants, as well as constituting an important source of cash for
many communities. Surface mining hazards include highwall collapse or slumping, rockfalls from pit sidewalls,
mudrushes while lashing rock, falling into unprotected pits, and falling from pit benches. Artisanal mining is labour-
intensive and is generally conducted utilizing manual digging methods e.g. shovels or hand chisels. Artisanal mining
varies from site to site, but is generally well structured despite its informality. Artisanal mining sites generally have
some inherent management structure and the extraction itself is often organized through teams of about 10 to 20 diggers
(Figure 1) who co-operate in one pit; and they are generally accompanied by supporting crews e.g. transporters, rock
crushers, mineral washers, and waste disposal crews.
Figure 1. A typical example of artisanal mining in central Africa
Artisanal mining is generally more dangerous than large-scale modern mining operations, as artisanal operations are
subsistence activities. The focus is on more immediate concerns than the long-term consequences of the activities.
2. Surface Mining 2014
94
When miners have no other source of income, they will usually find ways to evade controls and carry on working. It
must be noted that the introduction of machinery is often far beyond the economic reach of most artisanal miners; and
therefore there is a general tendency for workers to revert to more labour-intensive, and thus more risky, mining
methods.
The capacity of government to oversee the artisanal mining sector is limited and ineffective due to the inability to
cover the area under their responsibility, shortage of personnel, and a lack of capacity and technical knowledge. A wide
range of skills and abilities is currently used to exploit the varied deposits, but in general there is a low level of
understanding of safe and compliant mining.
Three types of artisanal mining operations typically exist: surface ‘pit’ mines, underground mining, and alluvial
mining. This paper focuses on the safety issues around artisanal surface mining and looks at providing practical
guidelines that should be considered when conducting artisanal or small-scale mining. The objective is to find a safe
and realistic approach to improving surface mining conditions, raising independent operators’ awareness of health and
safety issues, in a manner appropriate to local circumstances.
Safety issues
Artisanal miners often operate in hazardous working conditions. There are several major health risks associated with
artisanal mining:
• Exposure to dust
• Exposure to mercury or other chemicals
• Effects of noise and vibration
• Effects of overexertion and inappropriate equipment.
In addition, there are many accidents in artisanal mining. The five most frequently cited causes are as follows:
Rockfalls (Figure 2), subsidence, and tunnel collapses
• Lack of ventilation
• Misuse of explosives
• Lack of knowledge and training
• Obsolete and poorly maintained equipment.
Figure 2. A rockfall in an artisanal open pit
3. Safety aspects and recommendations for surface artisanal mining
95
Figures 3–11 illustrate some of the good and bad practices observed from various site visits. Figure 3 represent
typical examples of artisanal surface mining operations in central Africa, where water is often employed to saturate the
soil and tunnels dug into the highwall to facilitate collapse of the highwall. Although government regulations require
benching to be conducted it is obvious that no attempt is made to do so.
Figure 3. Typical artisanal mining and highwall collapse
Figure 4 shows a mining crew working adjacent to the edge of the highwall. In this case, workers are exposed to the
hazards of falling over the edge or slumping of the highwall. Figure 5 demonstrates the use of benching to improve
mining conditions.
Figure 4. Mining close to edge of highwall
4. Surface Mining 2014
96
Figure 5. Sketch of poor and good mining practices (Walle and Jennings, 2001)
Figure 6 and Figure 7 provide examples of benching in artisanal mining. In these examples, a dozer was used to
establish benching at the top of the mining pit. Figures 8, 9, and 10 illustrate undermining of the highwall. The mining
areas in Figure 9 and Figure 10 have subsequently collapsed. Figure 11 illustrates a severe highwall failure in which
the entire mining face collapsed.
Figure 6. An example of benching
5. Safety aspects and recommendations for surface artisanal mining
97
Figure 7. Mining activities on bench
Figure 8. A schematic of unsafe mining under a brow (Walle and Jennings, 2001)
Figure 9. An example of creating a brow
6. Surface Mining 2014
98
Figure 10. An example of undermining into a highwall
Figure 11. An example of a highwall collapse
Surface mining
The biggest concern with surface mining is the widespread practice of undercutting steep pit walls to follow
mineralized veins without a stable highwall or bench. Surface mining should be conducted utilizing bench mining
(terraced) methods. Access to the pit floor is often treacherous, with miners frequently carrying heavy loads (ore and/or
concentrate). Also, mining may take place adjacent to stronger, more competent rock, creating highwalls that contain
unstable blocks. As a general rule, workers should not work within 25% of the height of the highwall (the ‘drop zone’)
– for example, a bench height of 5 m would require a drop zone of 1.25 m. Note that there may be other considerations
that would warrant increasing this drop zone area in the case of highwalls above 5 m; for example, shear plane failure or
bench angles.
The best way to remove this risk is through bench mining. This can be done either by hand or by machinery such as
an excavator or dozer. The bench should be wide enough to prevent rocks dislodged from the highwall face from
rolling beyond the bench and into the pit. The width should also be sufficiently so that persons or machinery can
operate safely during excavation of the bench, without the risk of going over the edge.
Benches perform two important functions. Firstly, they provide stability to a highwall. Where a highwall contains
geological discontinuities i.e. joint sets, faults, slips, bedding planes, etc., providing benches can increase the stability of
the highwall. Secondly, where slumping of the highwall is a problem, benches can be used to keep materials from
falling into the pit (Figure 12). As a means to gauge the impact of falling rock, consider the following. A 75 mm rock
(1.2 kg weight) falling some 33 m yields a force of impact of approximately 450 kg. A 150 mm rock (9 kg) over the
same height would result in an impact force of over 3600 kg (3.6 t). A 300 mm rock (78 kg) over a 20 m height would
result in a force of 5800 kg (5.8 t).
7. Safety aspects and recommendations for surface artisanal mining
99
Figure 12. Potential accident hazard from falling rocks, and large rocks fallen from highwall
General safety issues
The following general safety issues should be seen as ‘quick wins’, which can be used to improve and communicate the
importance of safety within the artisanal mining community (Figure 13). Notably, it is not recommended that all
personal protective equipment (PPE) is required for all tasks; rather, key areas should be identified for the
implementation of the appropriate PPE.
• First aid equipment to be readily available and visible
• Introduction of sanitation facilities within the mining concession areas, requiring that the use of PPE (Figure 14
and Figure 15) be worn for the appropriate task being undertaken:
• Hard hats for underground workings
• Safety boots for all mining operations
• Eye protection for rock breaking duties
• Hand gloves when handling rocks and metal objects
• Dust masks for dusty areas.
• General training to identify key risks in mining, including the use of suitable visual aids to reinforce the
identification of risk
• Conducting of safety checks before the start of work, and the use of a central reporting system to highlight
incidents or problems.
Figure 13. An example of artisanal mining without PPE
8. Surface Mining 2014
100
Figure 14. Recommended personnel protective equipment (PPE)
Figure 15. An example of artisanal miners utilizing PPE
One way to reduce the risks associated with artisanal mining is to introduce alternative methods and/or equipment.
However, for artisanal miners to take up a new mining method or process there must be immediate and obvious
financial or timesaving benefits. Miners must be able to understand and trust the new methodology/technology. It is
important that whatever technology is introduced is also reviewed in regard to safety, as often one may introduce a
larger risk while attempting to mitigate the existing risk.
The implementation of mining standards in artisanal mining operations must be viewed in the context of the working
environment. Artisanal mining is currently subsistence work for most participants, thus safety standards may be seen as
interference and having a negative impact on a workers’ income. Therefore, it is critical that mine operators realize the
importance of safety and seek a balance between productivity and the need to improve working conditions. Standards
must be relevant, and the introduction of safety measures should be seen as a process requiring buy-in from a number of
stakeholders; starting with the miners themselves and including the mine owners if applicable, governmental agencies,
the community, and mineral buyers. Appropriate minimum standards should be identified and progressive improvement
in working standards established by all parties concerned. The implementation of mine health and safety standards
should be viewed as a process with immediate short-term, as well as medium- and long-term goals.
Artisanal miners must be able to understand the benefit of the proposed safety standards in order for change to take
place. Initial standards must be realistic and achievable so that immediate results can be seen, thereby encouraging the
miners to commit to and remain engaged in the process. Unrealistic goals will result in noncompliance and failure. To
some extent, mine operators will be required to enforce basic safety standards. Failure to comply should result in
corrective action being taken by the government (government agencies) and the threat of loss or suspension of the
mining right. Fines or other action should be used as further motivation to facilitate change.
It has been demonstrated that artisanal miners are willing to adopt safety standards and better practices. Rewarding
positive behaviour should be considered to jump-start the safety process so as to create a positive response. This could
9. Safety aspects and recommendations for surface artisanal mining
101
take the form of an increase in salary, or linking the purchase price of the metal/concentrate to general safety
compliance and performance. It must be understood by all participants that the transformation required will incur costs.
The cost of such action needs to be shared between owner, mineral buyer, and government.
Based on a daily rate of US$5 and an excavation rate of 5 m3
per 10-hour shift, manual benching is not capital-
intensive, requiring approximately US$6000 per month per worker. However, the introduction of this method will
initially require strict supervision to ensure the desired mining sequence is achieved. Also, the change in mining method
will most likely result in an increase in payment to the mineworkers, as manual labour requirements increase with
manual benching. Along with the introduction of bench mining, standards must be put in place to ensure that workers
adhere to basic safety and health principles.
Figure 16. Artisanal miners
Training
Training should be based on ‘practical theory’ combined with the practical application of the theory, i.e. ‘the doing’.
The following comments are made regarding establishing a training programme for artisanal miners and other parties
associated with artisanal mining:
• Training should focus on ‘the doing’ rather than just demonstrations
• When training artisanal miners, the training scheme should renumerate attendees to the equivalent of what they
could earn in full-time employment
• Mine operators and government officials should be encouraged to attend short courses dealing with a wide range
of issues, including the following:
• Minimum standards in regard to health and safety
• Demonstrations, ideally by equipment manufacturers’ representatives, of equipment for modest increases in
mechanization of mines
• Training in the area of finances (techno/evaluations). The principle would be to develop the understanding of
the benefits of re-investing in a mine, i.e. geological understanding of mineral resources, mine planning,
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mining and processing of the ore, and financial management are the foundation of an operation that should
assist in promoting growth and improved profits
Assisting mine operators to understand the basic concepts of surface mining
• Current working places should be assisted in becoming mines of best practice so that other miners can observe the
actual implementation of the theory. These should not be training centres as such, but operating mines that are
implementing best mining practices
• A core technical team to provide support and assist miners in improving safety and productivity. Initially, the cost
of the teams may need to be supported by a funding mechanism (e.g. governmental agencies/departments, non-
governmental organizations (NGOs), purchasers, etc.), but in the medium to long term, the costs of this technical
support should be funded by mine operators as a percentage of earnings from the sale of concentrate
• Governmental agencies/departments, NGOs, and mineral purchasers should assist in the promotion of training
programmes, i.e. short courses and best practice mines so that artisanal miners, supervisors, owners, and other
associates of artisanal mining can immediately improve their technical skills in terms of safety and mining.
Conclusions and recommendations
Artisanal mining operations are often unsafe and do not adhere to best practice. It is recommended that bench (terrace)
mining be undertaken to improve pit highwall conditions and general safety in surface mining. Bench mining can be
undertaken utilizing picks and shovels and wheelbarrows, with the potential to increase productivity through the
introduction of mechanization. Bench mining by pick-and-shovel should be the method of choice for remote operations
or concessions that have a limited life. Mechanized mining with dozers or excavators is currently being applied by
some mines, but the machinery is used intermittently, and if not systematically applied it still leaves the risk of highwall
instability.
Training combined with short courses and practical session should help to improve mining standards, conditions, and
productivity. It is recommended that best-practice mine sites be established and used to promote safe mining practices.
Reference
Walle, M. and Jennings, N. 2001. Safety and health in small-scale surface mines - a handbook. International Labour
Office, International Labour Organization, Geneva. ISBN 92-2-112475-4.