Tag Archives: ICMM

Global Tailings Review opens public consultation period

Environmental, Mining industry recognition, Water management, , , , ,

The ICMM-backed Global Tailings Review has launched a public consultation on its draft Global Tailings Standard in order to “develop a robust, fit-for-purpose international standard for the safer management of tailings”.

The public consultation, which ends on December 31, will take place in two parts.

First: online via a survey which has been translated into seven languages. Second: in-country consultations across a range of mining jurisdictions in the northern and southern hemispheres.

The Global Tailings Review was co-convened by the United Nations Environment Programme, International Council on Mining and Metals (ICMM) and Principles for Responsible Investment following the tailings dam collapse at Brumadinho, Brazil on January 25, 2019, to establish an international standard on tailings facilities management. The final Global Tailings Standard will need to be endorsed by all three parties.

The draft standard addresses six key topics:

  • Knowledge base – requires mine operators to develop knowledge about the social, economic and environmental context of a proposed or existing tailings facility;
  • Affected communities – focuses on the people living and working nearby. It requires human rights due diligence and meaningful engagement of project-affected people;
  • Design, construction, operation and monitoring of tailings facilities – aims to review design, construction, operation and monitoring of tailings facilities;
  • Management and governance – focuses on ongoing management and governance of tailings facilities. It defines a number of key roles, essential systems and critical processes;
  • Emergency response and long-term recovery – covers emergency preparedness and response in the event of a disaster, the re-establishment of ecosystems, and the long-term recovery of affected communities; and
  • Public disclosure and access to information – requires public access to information about tailings facilities in order for all stakeholders to be informed of the risks and impacts, management and mitigation plans, and performance monitoring.

“The review is committed to transparency and once the final standard is published, the Global Tailings Review will provide a consultation report that reflects feedback, key themes, topics and sentiments from different stakeholder groups, as well as how that feedback was processed and addressed in the final version of the standard,” the ICMM said.

It is expected that the final standard and accompanying recommendations report, which will outline broader proposals to support the uptake and implementation of the standard, will be published in 2020.

The ICMM publishes mining climate change report

Environmental, Mining events, Sustainable mining, Water management, , , , ,

The International Council on Mining and Metals (ICMM) has launched a report ‘Adapting to a Changing Climate: Building resilience in the mining and metals industry’ at WWF’s Water Summit 2019 in Frankfurt, Germany, today.

The report shares learnings from ICMM’s company members on how to build operational resilience and how to assess and manage the physical impacts of climate change at mine sites, it said. “It provides practical guidance that aims to help the mining and metals industry build climate resilience by enhancing the sustainability of communities and ecosystems, limiting future liabilities, safeguarding business continuity and making prudent investments,” the ICMM said.

ICMM company members recognise the need for an urgent global response to the threat of climate change across all areas of society and the economy, according to the ICMM. “They are committed to being part of the solution by mitigating CO2 emissions at site level and across the supply chain, building resilience to adequately respond to climate related risks and continuing to contribute to the sustainable production of commodities essential to the energy and mobility transitions.”

Earlier today, during a panel discussion at the Summit, Tom Butler, CEO of ICMM, said: “Our climate is changing, and this presents challenges for the mining and metals sector. Understanding this challenge, ICMM has collated insights and developed tools that can support our members and any responsible mining company to build resilience by identifying and properly managing these risks.

“Fundamental to the way ICMM operates is sharing knowledge and experience with each other and I am pleased today to share what we have learned so far with the publication of this report.”

Wabtec on the evolution of collision awareness systems in mining

Automation, IoT, Mining equipment, Mining policy, Mining safety, , , , , , ,

In an article arguing proximity detection and collision awareness technology makes for not only a safer, but more productive mine, Craig Hoffmann, Senior Product Manager – Collision Awareness & Geospatial Systems at Wabtec Corp’s Digital Mine division, has revealed that the company is currently working on conducting single and multiple machine testing on a production mine site using its collision awareness system.

In an opinion piece titled, Pioneering collision awareness technology enables safer mining practices, Hoffman went into the history of this technology, as well as the milestones the Wabtec team have achieved.

Mining has always been seen as a risky business, whether undertaken above ground or deep beneath the earth’s surface. But, thanks to a combination of government regulation in South Africa and a concerted industry effort by mining companies and original equipment manufacturers (OEMs), further enabled by cutting-edge technology, it’s becoming a lot safer, he writes.

In several respects, South Africa is leading the way in this drive towards the ideal of a mining industry with zero avoidable fatalities. Collision awareness is a crucial component of this quest, contributing to the layers of protection against significant risk associated with vehicle interactions.

A collision awareness system (CAS)* is an integral part of mine safety management tools that helps workers make the right decision at the right time in order to mitigate vehicle interaction risk while helping to increase productivity and improve situational awareness.

The need for a CAS in South Africa was identified as far back as 1995, when the Leon Commission of Inquiry into Safety and Health in the Mining Industry identified haulage and transport accidents as the second largest category of accidents in mines.

The government wasn’t slow to respond. A year later, the Mine Health and Safety Act was enacted, which places the responsibility on employers to ensure mines are safe and workplaces healthy.

At the same time internationally, there was a concerted move towards making interactions between vehicles, vehicles-to-persons and vehicles-to-environment significantly safer. The Earth Moving Equipment Safety Round Table (EMESRT) was established in 2006 by six global mining companies. From the outset, engagement with OEMs was seen as crucial to the success of its efforts.

Since its formation, EMESRT, as part of the Vehicle Interaction Systems Performance Requirements PR-5A, has defined 24 surface vehicle interaction scenarios and established nine levels of vehicle interaction defensive controls, namely: level 1 – site requirements, level 2 – segregation controls, level 3 – operating procedures, level 4 – authority to operate, level 5 – fitness to operate, level 6 – operating compliance, level 7 – operator awareness (proximity awareness – alerts the operator), level 8 – advisory controls (proximity detection – advises the operator) and level 9 – intervention controls (collision avoidance – takes control from the operator). EMESRT has also driven the mining industry development of a standard communications protocol between the proximity detection system (PDS) and OEM machine for the practical implementation of level 9 – intervention controls as part of the standard ISO 21815.

The importance of level 7 – operator awareness and level 9 – intervention controls was highlighted on February 25, 2015 when the South Africa Minister of Mineral Resources signed the Amendment of Chapter 8 of the Mine Health and Safety Act. This legislation makes it necessary to implement a system which provides proximity awareness (level 7) and collision avoidance (level 9), which will automatically apply the brakes to trackless mobile machinery (TMM) without any human intervention at any mine where there is a significant risk of such collisions.

This functionality essentially requires the traditional level 7 PDS to mature to provide full machine interventions of a level 9 collision avoidance system. The final date for implementation is still to be confirmed but the mining industry is targeting late 2020.

The legislation requires that each mining operation conduct a comprehensive risk assessment to determine the risk exposure introduced by TMM. Based on the risk assessment, the mining operation is then able to define a collision management system user requirements specification with regards to CAS required on the TMM fleet.

The need for such measures was underlined when it emerged that fatalities attributable to TMM-related accidents increased nearly 50% from eight in 2016 to 14 in 2017.

Wabtec Digital Mine has been the global provider of a best of breed high integrity level 7 PDS system for the past 14 years and, therefore, was perfectly positioned to take on the journey to progress towards a fully compliant level 9 CAS system. At this level, the PDS automatically applies full intervention controls to the vehicle and takes control from the operator when a dangerous vehicle interaction situation is detected after the operator has failed to respond to the earlier level 7 proximity alerts and level 8 advisory controls.

It is recognised by Wabtec and the mining industry that CAS alone should not be viewed as a ‘silver bullet’ for mitigating the risk of vehicle interactions, as the initial focus should be on maximising the maturity of the more effective mine site defensive controls at levels 1 – 6 and supplemented by PDS/CAS levels 7 – 9 where required. This approach has also been adopted through a new initiative by the International Council on Mining & Minerals (ICMM) as part of the program for ‘Innovation for Cleaner Safer Vehicles’, where the mining industry globally has an ambition at the CEO level to eliminate all fatalities from vehicle interactions in mining by 2025.

The Minerals Council of South Africa is currently coordinating the development and testing of all the CAS suppliers by providing a best practice framework with the aim of fast tracking the industry developments. This work is also being integrated into a new EMESRT initiative to develop a unified, integrated industry PDS testing methodology and validation framework.

Milestones

The first milestone for the CAS supplier is to conduct independent lab scale testing done by the University of Pretoria (UoP) at the Gerotek testing facility, in South Africa. The UoP uses high precision measuring equipment to test and log the performance of the CAS system as is capable of providing a detailed independent report on the capability of the CAS system. The tests provide invaluable insights into the capability of the system and level of technology readiness.

The second milestone, which the Wabtec Digital Mine Collision Awareness System team conducted on an independent machine OEM site, is single and multiple machine testing. These tests were successfully performed, as real-world scenarios were created and tested against. These tests were conducted in dry and wet conditions and to speeds up to 40 km/h.

The third key milestone that the Wabtec team is currently working towards is to conduct single and multiple machine testing on a production mine site. The range of machines being tested include rigid body haul trucks, articulated dump trucks and a rubber-tyred wheel loader, which represent the typical high risk TMM found working on a mine site.

In order to address the significant challenges in achieving a level 9 – compliant CAS system, Wabtec Digital Mine has developed proprietary software algorithms that are able to interpret and anticipate the complex scenarios presented during normal mining operations. This enables the Wabtec systems to operate seamlessly with the operator.

If Wabtec’s experience has shown anything, it’s that proximity detection and collision awareness technology makes for not only a safer, but a more productive mine, thanks to the wealth of data the systems are able to gather, analyse and feed back to the mine operators we support. We remain committed to delivering a world class, Level 9 CAS system to the global mining community.

* “CAS” has been alternately referred to as collision awareness system or collision avoidance system. Wabtec CAS solutions should be understood as collision awareness systems

Anglo American’s FutureSmart Mining on its way to tangible technology results

Automation, Base metals, Bulk handling, Coal technology, Comminution of minerals, Environmental, Explosives and blasting, IoT, Mineral processing, Mineral project development, Mining equipment, Mining industry recognition, Mining people, Mining policy, Mining safety, Mining services, Mining software, Mining techniques, Steel and iron ore, Sustainable mining, Water management, , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , ,

“It’s clear that the pressures on us are unsustainable, whether it is around our carbon footprint, water footprint, or physical footprint, and we are always looking for different ways to push us in this future direction where our footprint will be very different.”

Tony O’Neill, Anglo American Technical Director, knows the company he works for is up against it when it comes to retaining its reputation as one of the world’s leading sustainable mining companies.

It’s clear from the company’s 2018 sustainability report – which saw it achieve a best-ever performance in terms of injuries, a cut in energy use and an increase in greenhouse gas emission savings – that Anglo is going down multiple paths to reach its goals. O’Neill, who joined the company almost six years ago, believes Anglo’s FutureSmart Mining™ programme will play a major role in confronting and overcoming many of the issues it (and the industry) is facing.

“If you look at FutureSmart Mining, at its absolute essence, it is about footprint; how do you change the footprint of mining? How do you have a mine that draws no fresh water? Mines without tailings dams? Mines that look very different?” he told IM.

“It’s getting people to believe there is a different way for mining in an industry that has, to this point, been quite traditional. It is not going to happen overnight, but I think we have a genuine vision that is, in my view, quite feasible.”

IM spoke with O’Neill and Donovan Waller, Group Head of Technology Development, this week to get to the bottom of how technology is making Anglo ever more sustainable.

IM: Could you explain how the Anglo operating model facilitates and fosters innovation within the context of FutureSmart Mining?

TO: The Anglo American operating model is the chassis that underpins everything, giving us certainty in the delivery of our work. When you have got that stability – and the lack of variability – in your business outputs, it is much easier to overlay new technologies and processes. When you then see a difference in operating or financial results, you can confirm it is down to what you have implemented, rather than the underlying processes.

I look at it a little bit like a three-legged stool: you have the operating model on one leg, the P101 benchmark-setting on another, and technology and data analytics on the third leg. They all co-exist in this system and work off each other. Without one, the stool falls over.

The operating model has given us a drumbeat of delivery, and we get the licence to innovate because of this drumbeat.

IM: Do you think FutureSmart Mining is starting to be understood and valued by investors?

TO: They’re awake to it now. I think it is still in the early stages of the story, but they can see what we are doing and the ambition behind it. Ultimately, it will result in a different investment profile, or more investors because of it, but I am not sure that it’s translated in full up to now. The recognition has been more around the general results of the company.

With all these technologies coming through – much of them driven by higher levels of data and the ability to interrogate that data – the vision we imagined way out into the future, I think, is a lot more tangible than when we started out four years ago.

IM: Out of all the tailings dam elimination work you are carrying out (around passive resistivity, fibre-optics, micro-seismic monitoring, coarse particle recovery, polymers, and dry stacking), which innovation will have an impact on Anglo’s operations in the next three-to-five years?

TO: All of them. We started out with our tailings programme in 2013; in fact, our group technical standards were re-issued at the beginning of 2014 and they are now one of the main guidelines the ICMM (International Council on Mining and Metals) uses.

Tailings dams have always been at the back end of the mining process and, in a way, the science behind them has never been part of the mainstream operation. Our view, internally for many years, is tailings dams are one of the industry’s greatest risks.

“Our view, internally for many years, is tailings dams are one of the industry’s greatest risks,” Tony O’Neill says

Ultimately our aim is to eliminate tailings dams. Period. Coarse particle flotation – getting that coarser particle size that drains much more freely – is core to that and you can see a development pathway there. For example, with some of these new flotation techniques, we now only need 1% exposure of the mineral for it to be effective. In the past, it was much higher.

When we upgraded the capability of our tailings organisation, it became clear we needed to get a lot more data off these tailings dams. About three years ago, we started putting fibre-optic sensors into the dams. We have since developed, through our exploration arm, passive resistivity seismic monitoring, which basically tells you where your water sits in the dams. And, we’re putting into Quellaveco micro-seismic measuring techniques, which will be more granular again. You can see the day coming really quickly where tailings dams are a real-time data source for mining companies.

We’re also, with our joint venture partner Debswana, building the first polymer plant in Botswana, which could have an impact on dry tailing disposal.

The thing we need to crack – both ourselves and the industry – is how to dry stack at scale. At the moment, that is still a work-in-progress, but it is doable in the long term.

IM: How is the bulk sorter you have operating at El Soldado, which is equipped with a neutron sensor, working? How has it made a difference to recoveries and grades at the operation?

TO: With the bulk sorter, we’re taking packages of tonnes rather than individual rocks to enable us to get both speed and volume. At El Soldado, we are sorting in four tonne packages. You can adapt the sorting profile by the characteristics of the orebody. We’re generally looking to sort tonnages that are less than you would put in a haul truck body or bucket.

If you step right back, in the past, most processing plants wanted to blend to get an average feed. We are going the other way. We want to use the heterogeneity of the orebody to its advantage; the less mixing we can get ahead of these sorting processes, the better it is for recoveries.

Being able to remove an orebody above the cut-off grade alongside waste tonnages and upgrade the latter has led to an effective lift in head grade. It has been enabled by new sensing technology with a particular type of neutron sensor.

What we have seen in early results has surprised us on the upside. We thought we would see a 5% uplift in head grade, but in fact we have seen about 20% – to qualify that, it’s in its early stages.

O’Neill says the bulk sorting trial at El Soldado has seen about a 20% uplift in head grade in its early stages

If you take this to its logical conclusion, you can see the day coming where you would cut the rock – no drilling and blasting – immediately sort the rock behind the machine cutting it and distribute said rock efficiently into its value in use; you don’t have stockpiles, you have plants sensing the material right through and adapting in real time to the change in mineralogy. I think there is another 3-4% increase in recovery in that whole process when we get it right.

Our sweet spot when we created FutureSmart Mining was always the orebody and processing plants, more so than automation (although that is part of the potential mix). That was different to a lot of the other players in the industry. This focus could lead to the development of different types of plants; ones that are flexible, more modular and you can plug and play.

IM: Do you see these type of neutron sensors being applied elsewhere across a mine site?

TO: Yes, through processing plants and conveyors. In fact, we’re preparing for this on conveyors right now.

What we have found with all this new technology is that, when we implement it, quite often another opportunity arrives. They end up playing off each other, and that is the context for the bulk sorting and coarse particle flotation.

IM: How have Anglo’s Open Forums played into these developments?

TO: We have held eight Open Forums on sustainability, processing, mining, exploration (two), future of work, energy and maintenance.

Out of those eight, I think we have got around 10,000 ideas from them. These forums have been specifically designed where only about a third of participants are from the mining industry, with the other two thirds coming from the best and brightest analogous industries we can tap into – automobile, oil & gas, food, construction, even Formula 1 racing and NASA.

The reality is that out of those 10,000 ideas, the success rate is about 1:1,000, but the one that makes it is quite often a game changer.

IM: Going back to the bulk sorters, am I right in thinking you plan to put these into Mogalakwena and Barro Alto too?

TO: The aim is to have them across our business. At El Soldado, the copper angle is very important. The technology – the sensing and using the data – is probably a touch more advanced in copper, but we are building one currently in our PGMs business at Mogalakwena and a bit behind that, but ready to be built, is one in nickel, yes.

In terms of our programme, you will see them spread across our business in the next, hopefully, 18 months.

IM: Where does your approach to advanced process control (APC) fit into the FutureSmart Mining platform?

TO: We want to have APC in some form across all our business by the end of this year. We have probably come from a little behind some of the other players in the industry, but we’re pushing it quite aggressively to give us the platform for data analytics. The upside we have seen just by putting the process control in so far has surprised me a bit – in a good way; power reductions, throughput, having this different level of control. All of it has been pleasing.

We spent about 12 months looking at the whole data analytics space to see how we were going to implement our solution. If you look around at the sector, everyone wants to be involved and profit share. If you add it all up, you could end up with not a lot of profitable pieces at the end. We have strategically chosen the pieces we think are important to us and our profit pool and have been happy to be a little looser on some of the non-core areas.

The other key plank to the APC is that we own the data. The reality is, in the new world, data is like a new orebody and we’re not willing to let go of that.

IM: Your Smart Energy project involving a haul truck powered on hydrogen has certainly caught the attention of the market: how did you come up with this innovation?

TO: Initially, we couldn’t make renewables work from an investment criteria perspective – it was always close, but never quite there. Donovan’s team then took an approach where they said, ‘forget the normal investment criteria. All we want to do is, make the business case wash its face.’ In doing so, it enabled them to oversize a renewable or photovoltaic energy source – the power plant – using that extra power to produce hydrogen and putting that hydrogen to use in the haulage fleet. Re-engineering the haulage fleet gave us the business outcomes we were looking for.

DW: These business cases bring you to temporary barriers. When you hit that temporary barrier, people normally stop, but what we said was, ‘OK, just assume it is not there and go forward.’ That brought the whole business case back again by looking at it differently again.

Anglo’s Smart Energy project is aiming to power a 300-t class truck with hydrogen fuel

IM: Where is this project likely to be situated within the group?

TO: We’re still not 100% fixed as the initial work will be done here (the UK). You are talking about quite specialist skills working with hydrogen.

When the system has gone past its initial testing, it will go to a site, probably in South Africa, but we are not 100% locked into that at this point.

IM: On the 12-month timeline you have given, when would you have to be on site?

TO: The infrastructure will be pre-built here in the UK. We’re effectively testing it here. In a way, the physical truck is the easy bit.

It’s going to be using a 300-t class truck. The guys have already done quite a bit of the detailed measuring and the design elements are well under way.

We’ve also taken the approach to use pre-approved technology, which Donovan can talk about.

DW: This minimises the risk on the first go and allows us to, later, tailor it. For example, if you don’t have a right sized fuel cell currently available off-the-shelf, you just use multiple standard-size fuel cells for now. Then, when you get into the final version you could tailor them into something more specific.

IM: On mechanised cutting, you recently mentioned the building of a “production-sized machine” for at least one of your mines in South Africa. Is this a variant of the Epiroc machine – the Rapid Mine Development System – you have been using at Twickenham?

TO: It’s the next generation of machines. It’s fair to say that, in the last 12 months, the technology has come to the point where we are confident it is viable.

What we’re looking for is a fundamental breakthrough where, for example, we can take the development rates up three or four times from what you would usually expect. That is what we’re chasing. It would involve some sort of pre-conditioning of the rock ahead of the cutting, but the cutting, itself, works.

For us, mechanised cutting is a real solution to some of the safety issues we have had on our plate. Regardless of whether it goes into South Africa or another underground mine, we see it as a key part of our future underground design and operation.

IM: What type of rock pre-conditioning is this likely to be?

TO: I think around the world, people are looking at electricity, microwave, laser, a whole suite of things. None of them have yet quite landed, but they all have potential.

IM: Where does haul truck automation fit into the pipeline for Anglo American?

TO: All the equipment we buy, going forward, will be autonomous-capable, which means we can run it in either format (manned or unmanned). You are then left with a number of decisions – have you got the design to retrofit automation? Is there a safety issue to be considered? Is there a weather issue to contend with? There are a whole series of gates that we’ll take it (automation projects) through.

It’s good to go back to P101 here. Where P100 is getting all of our key processes to world-class benchmarks, P101 is about establishing a new benchmark. By definition, if you get your operations to that point, the gap between that manned performance and autonomous performance is not that great.

Autonomy is part of our future armoury, but when and where and how, we’ll have to wait and see. For example, we are currently looking at the option of autonomous haulage trucks at one of our open-cut mines in Queensland.

When you look at our portfolio of operations, it’s often a more complex environment than when you are just working in the wide open Pilbara.

BHP establishes task force to handle tailings dams

Environmental, Mining industry recognition, Mining maintenance, Sustainable mining, Water management, , , ,

BHP says it is establishing a dedicated Tailings Task Force to drive enhanced focus on internal dam management plus support the development of international best practice.

The announcement came during an environmental, social and governance briefing where the company also revealed it is “progressing the investigation of new technologies to further mitigate current dam risks and eliminate future risk”.

BHP has interests in 67 operated tailings facilities across all its sites. Of these, 13 operated facilities are active, (12 in Australia, one in Chile), 29 are operated upstream facilities (five of which are active). In addition, its non-operated joint ventures have nine facilities, five of which are upstream, of which all are inactive.

Back in 2016, the company carried out a Dam Risk Review, which identified no immediate concerns regarding dam integrity. This was undertaken to assess the management of tailings facilities following the failure of the Fundão dam at Samarco (a joint venture with Vale).

BHP has since undertaken Dam Safety Reviews which provide assurance statements on dam integrity, the company said.

The company said on the appointment of the task force: “Prior to Brumadinho we already had a significant focus on looking at how we could deliver a step change reduction in tailingsrisk. Brumadinho however has further strengthened our resolve.”

The new Tailings Task Force will be accountable for further enhancing the company’s focus on tailings including the continued improvement and assurance for BHP’s operated tailings storage facilities, the company said. It will also progress its technology efforts and ongoing participation in the setting of new international tailings management standards.

On the latter, BHP said it continued to work with the International Council on Mining and Metals its peers to “drive a step change in tailings management across the sector”.

Miner fatalities dropped in 2018, ICMM says

Mining policy, Mining safety, Mining services, Sustainable mining, , , ,

The International Council on Mining and Metals (ICMM) recently released the 2018 safety data of its company members, which showed the industry suffered 50 fatalities last year.

“ICMM and its members are committed to strengthening health and safety performance and reducing operational fatalities to zero,” the ICMM said. As part of this commitment, ICMM publishes an annual safety data report of its company members. The full report, Benchmarking 2018 Safety Data: Progress of ICMM Members, is available here.

The 2018 safety data report, which collates the safety data of around 1 million workers and contractors, recorded 50 fatalities in 2018. This was a decrease from 51 fatalities in 2017 and 63 fatalities in 2016, the ICMM said.

Eleven of ICMM’s 27 company members reported no fatalities in 2018, compared with eight in 2017. These were: Africa Rainbow Minerals, Barrick, Freeport McMoRan, Goldcorp, JX Nippon, Minera San Cristóbal, Minsur, Mitsubishi Materials, Newcrest, Orano and Sumitomo.

The number of hours worked across ICMM’s members increased by 16% due to data being included from new company members, Minera San Cristóbal, Minsur, Newcrest and Vale, the ICMM said. While total fatalities dropped by 2%, the fatality frequency rate dropped 19% from 0.027 to 0.022 fatalities per million hours worked, the council said.

There was also a drop in the injury rate from 3.94 in 2017 to 3.41, despite an increase in the number of recordable injuries from 7,515 to 7,751.

Tom Butler, ICMM’s CEO (pictured), said: “ICMM and our company members are determined to eliminate fatalities from their operations. The single highest cause of deaths in 2018 was from mobile mining equipment which is why we are exploring collision avoidance technology in our Innovation for Cleaner, Safer Vehicles programme.”

The report findings include:

  • One fewer fatality recorded in 2018 compared with 2017;
  • Eleven member companies recorded no fatalities in 2017, an increase from eight in 2017;
  • Fifteen fatalities (30%) were caused by transportation/mobile equipment, four higher than the 11 fatalities recorded in 2017;
  • Nine fatalities (18%) were caused by fall of ground in underground mines, eight fewer than the 17 in 2017;
  • In the six years of safety data published by ICMM, fatalities have dropped from 90 in 2012 to 50 in 2018 and, in this time, the fatality frequency rate has dropped by 33% to 0.022 deaths per million hours worked;
  • Total recordable injuries increased from 7,715 to 7,751 although the frequency rate reduced from 3.94 to 3.41 recordable injuries per million hours worked, and;
  • Since 2012, total recordable injuries have dropped from 13,895 to 7,751 and the total recordable injury frequency rate has dropped by 33%.

The report also examines incidents by country. The highest number of fatalities (14) occurred in South Africa, where 400 million hours were worked. There were six fatalities in Chile and Ghana where respectively 281 million and 51 million hours were worked.

The highest fatality frequency rates were recorded in Hungary, Spain and Laos which each recorded a single fatality, the ICMM said.

This benchmarking report provides the safety data from ICMM companies for 2018 and does not include fatalities from the Brumadinho tragedy that occurred in January 2019.

Cummins powers up for the future of mining

Environmental, Mine ventilation, Mining equipment, Mining services, Power supply for mines, Sustainable mining, , , , , , , , , , ,

Mining operations are embracing the opportunities created by new technology, from automation and electric vehicles to renewable energy, but what can traditional fossil fuel power generation contribute to this technology-led evolution of mining? Craig Wilkins, Director Prime Power at Cummins, explains how natural gas power is key to meeting the industry’s power needs in the coming decades.

Many mining operations take place in remote parts of the world where access to large electric utility feeds is either unavailable or requires significant investments in electrical transmission and distribution. These same sites may also have little or no access to pipeline gas, or experience a variation of natural gas supply. In addition, they are operating in the most extreme climates imaginable, faced with blistering heat, the wettest humidity and high altitudes.

Therefore, the need to secure a reliable prime and peaking power supply to keep production up and running 24/7 is paramount.

Cummins has responded to this challenge with a significant investment into the natural gas arena with the launch of its HSK78G gas-powered generator, a flexible prime power solution for heavy-industry installations in the most extreme environments. Its extreme engineering is designed to push the boundaries of performance and challenge the perceived limitations of natural gas generators for mining operations. It has barrier-breaking fuel flexibility, able to burn pipeline natural gas, flare gas and biogas, even the lowest BTU methane down to 40MN, and free fuel sources, with high efficiency and low emissions.

The investment on the HSK78G comes as the power market across the globe is changing. Technological advances in renewable energy and its application with batteries as part of modular power networks, tend to dominate the future of power generation. The concept is flexible, scalable and able to power entire cities as well as remote off-grid installations – such as mines. So why invest in traditional natural gas power?

Gas vs diesel

Miners continuously look for ways to lower their cost of production.  One of the major sources of cost for an open-pit mine site is fuel.  Some mines have access to an un-interruptible supply of natural gas that offers them a lower total cost when compared to diesel. 

Although technological advancements in natural gas storage and filling have yet to yield an economical replacement to diesel engines in mobile mining equipment, prime power generator sets are quickly moving towards lean burn, natural gas technologies. Lean burn gas powered generator sets use twice as much air in the fuel/air mix than required for total burn, which lowers burn temperature and NOx output, ensuring compliance with emission regulations.

Due to increasing emissions limits being adopted for generator sets, diesel generators sometimes are limited in their use. Lean burn, natural gas generator sets typically have ten times lower NOx than diesel equivalents (250-500 mg/Nm3 for natural gas compared to 2,500-3,000 mg/Nm3 for diesel.) Also, lean burn particulate levels are almost zero, so meeting location specific emissions regulations can be far easier across a global perspective.

Power generation fuel flexibility

Technological advances in design, running in tandem with market change, will result in gensets that can use fuel efficiently in varying qualities. This innovation is demonstrated by our new HSK78G, which delivers high electrical efficiency of up to 44.2% (50 Hz) and 43.5% (60 Hz) on a range of pipeline natural gas down to 70 methane number (MN) without impacting power output and efficiency.

Ultimately this fuel flexibility empowers operators to derive clean power from what would otherwise be regarded as waste products, at worst emissions. The technology for smarter and cleaner power solutions is speeding up and adoption will continue to grow as more mines embrace its capital expenditure (capex) and operational expenditure (opex) advantages.

Engineered to extremes

A further challenge for the mining operation is the environment in which the generator set operates. As engines operate, they produce heat and tend to be more sensitive to the ambient temperature levels. A generator’s ambient capability is defined as the maximum temperature at which it can operate without experiencing a loss of efficiency and it is an essential factor for customers operating in such extreme environments.

Without an engine capable of meeting high ambient temperatures, customers risk having to derate their engine, which can lead to reduced power efficiency and shorter operational life from the generator or having to stop it altogether. The HSK78G has been designed to operate at the highest ambient temperatures in the most remote locations, all far from the closest grid, offering full power capability without derating at 50°C (122°F) and 500 m (1,640 ft).

Gas vs renewables

The focus of many customers is to achieve the optimum levelised cost of electricity (LCOE) given the availability of different technologies which are suitable for their application. This can range from 100% gas generation through to a balanced mix of renewable sources such as wind or solar, and complementary storage technologies that leverages the reliability of gas generation to ride through periods where renewables are limited by their cyclical nature. The technology mix utilised will drive the different capex and opex cost scenarios that will ultimately affect the LCOE.

Improvements in gas engine technology, such as in the new HSK78G engine from Cummins, have pushed maintenance and overhaul limits well beyond the traditional envelope, thereby lowering opex costs over time. Jointly, we will continue to see cost reductions in storage and battery technology as volumes increase. For the near future, however, miners will continue to look for mixed technology to balance their capex and opex trying to achieve the lowest LCOE for its sites.

Preparation for electrification

As much as 40% of an underground mine’s energy outlay is spent on powering ventilation systems to remove pollutants from tunnels. Reducing the use of fossil fuels underground could have significant cost benefits for underground mines. In addition, The International Council on Mining and Metals have set their vision to provide solutions for minimizing the impact of underground diesel exhaust by 2025. As more underground mining vehicles and equipment contemplate the potential benefits of electrification, Cummins will continuously invest in power systems that will be ready to support such power need and respond to any changes in the mining industry

The right technology choice

In the future most power systems will require a mix of technologies that are specifically suited to their environment, emissions zone and location.  Natural gas power offers mining operators an efficient and proven and prime power solution. From Cummins perspective, a lot of investments are made in new gas engineering technology, which are demonstrated with the HSK78G gas series. Additional product investments are being made within the 500-1 MW space, which will be released later this year, offering a comprehensive gas product portfolio to meet all market requirements. Progressively stringent global emissions standards are also driving Cummins investment into a variety of technologies – natural gas, diesel, batteries and fuel cells, to ensure that customers have the right power for the right application.

ICMM launches Health and Safety Conference report

General, Uncategorized,

ICMM has launched the report of the Health and Safety Conference held in Santiago, Chile, in November 2012. The conference consisted of 19 companies and over 300 delegates including five chief executives. The report highlights the importance of collaboration, culture and leadership which was a common message heard throughout the 19 sessions that took place during the conference. The vehicle safety aspects of the conference were extensively reported in International Mining’s April issue, pp64-76. Continue reading ICMM launches Health and Safety Conference report