Tag Archives: underground mining

GMG publishes new short interval control guideline

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The Global Mining Guidelines Group (GMG) says it has published the Guideline for Implementing Short Interval Control (SIC) in Underground Mining Operations.

SIC is a structured system in which data from mining processes are periodically reviewed and action is taken in response to them, GMG explained. “This guideline provides a roadmap to increase the speed and likelihood of success during SIC implementation while avoiding common pitfalls.”

Specifically, the publication presents a conceptual model of what SIC could look like that includes an operational framework, detailed workflows, and an outline of data enablement at various levels of maturity, according to GMG.

SIC has only recently begun to be used in underground mining, although it has a long history in the manufacturing industry.

GMG said: “One challenge in implementing SIC is tailoring it to the operation at hand because underground mining conditions can be unpredictable, but the guideline offers mining stakeholders a base of knowledge of how it can be applied.”

Greg Sandblom, Operation and Business Technology Lead at Sudbury Integrated Nickel Operations, a Glencore Company, says the guideline “can provide a valuable reference to mining companies during all phases of SIC deployments at existing mines or new mine projects”.

He continued: “It can effectively act as a checkpoint to validate that lessons learned and experience from leaders across the mining industry are applied to their implementations.”

Lisa Önnerlov, Development Engineer – Industrial Design at Boliden, said there was potential for the application of the guideline for those already using a SIC system.

“Even though we have been working with SIC for many years, we still have a lot to improve,” she said. “We face challenges like refining the overall coordination and to take advantage of new technological possibilities and make it useful in reality. We hope that this guideline will be a tool for both benchmarking and as a common reference in collaboration with other mining companies working with SIC.”

SIC has the potential to increase productivity and lower costs, according to GMG. As the practice becomes more common, it will, in turn, become increasingly accessible, according to Gordon Fellows, President of Fellows Mining and Digital Solutions.

“Achieving the greatest benefit from SIC comes from monitoring and controlling the shortest interval, but results are possible even at lower levels of maturity and at lower cost,” he said. “As technology evolves, it will make it simpler and less expensive to reach higher levels of maturity.”

One highlight of the process of developing the guideline, according to Liv Carroll, Senior Principal, Mining Transformation and Applied Intelligence at Accenture, has been the input from and cooperation between various stakeholders in the mining industry.

Carroll said there had been “effective collaboration between operators, service providers, consultants and technology specialists alongside the GMG team; our industry working as one for the benefit of all”.

She added: “In working together, we have drawn on a breadth of global and diverse experience to amalgamate leading practices into the guideline considering all levels of maturity and allowing for future evolution.”

Looking ahead, implementing SIC offers great potential for positive change in the industry because it facilitates better planning, quicker decisions, increased production, lower costs and creates a safer working environment, according to GMG.

GMG Chair, Michelle Ash, says: “I am very excited to see the publication of the SIC guideline because it is not only the culmination of a lot of work from many people, but also a fundamental building block for the transformation of our industry. I am looking forward to visiting mines post implementation and seeing the case studies that arise from their efforts.”

Hindustan Zinc after improved safety, productivity with Epiroc’s Mobilaris solution

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Hindustan Zinc, India’s only zinc-lead-silver producer, has selected Epiroc to equip its flagship Rampura Agucha mine with Mobilaris Mining Intelligence™ (MMI).

A decision support solution for mine safety and efficiency, MMI enables superior situational awareness and is designed to visualise and support mining operations in all its complexities, in real-time, Epiroc says.

Hindustan Zinc has introduced various technologies and innovations and has obtained success in enhancing safety, efficiency and exploration, according to Epiroc.

Back in 2017, the miner looked to automate many of its operations, acquiring Epiroc drill rigs, LHDs, haul trucks (including the MT65) and exploration equipment to be used in five of its mines in northwestern India. The automation and other high-technology features of the equipment were enabled through the common Rig Control System, with most machines are equipped with the telematics solution CERTIQ.

Following the latest MMI order, Sunil Duggal, CEO, Hindustan Zinc, said: “We are continuously making efforts to develop better, connected and intelligent mines. The partnership with Epiroc will support our direction to develop safer and more productive operations at Rampura Agucha mine”.

Ulla Korsman-Kopra, Global Business Manager, Automation and Information Management at Epiroc, said the company would support Hindustan Zinc’s operational (mining) improvement processes with the MMI solution. “The globally-acclaimed features will take Hindustan Zinc’s operations to the next level of performance gains,” she said.

The MMI portfolio features situational awareness, short interval control, including machine data integrations, and traffic awareness promises to get maximum productivity and efficiency out of a customer’s mine, according to Epiroc.

“Thanks to the openness and transparency of the MMI solution, integrations with mixed fleet machines, sensors and more will create the foundation for vital real-time analytics,” Korsman-Kopra said.

The system is expected to be operational during once the networking is up and running at the Rampura Agucha mine.

Rampura Agucha is the second largest zinc mine in the world, according to Hindustan, with production of 3.9 Mt in the company’s 2018 financial year. It has a zinc-lead reserve grade averaging 15.7% Zn+Pb, with total reserves of 46 Mt as of March 31, 2018.

The ongoing underground mine project is being developed with a vision of producing 5 Mt/y of ore and includes a main production shaft of 955 m depth, 7.5 m diameter and hauling capacity of 3.75 Mt/y; two ventilation shafts, two declines from surface and paste fill plants, according to Hindustan.

OZ Minerals outlines block cave potential at Carapateena copper-gold project

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OZ Minerals’ scoping study on an expansion at the Carrapateena copper-gold project, in South Australia, has shown that converting the lower portion of the sublevel cave to a block cave from 2026 could yield up to 60,000 t/y more copper output at the same time as reducing operating costs.

The Carrapateena sublevel cave is still in the development phase and is expected to hit first production in the December quarter of this year. This project is expected to produce an average of 65,000 t/y of copper and 67,000 oz/y of gold over a 20-year mine life.

The study outlined a more than doubling of mine throughput from 4.25 Mt/y to 10-12 Mt/y from 2026 through the development of the block cave and expanded surface infrastructure. This was expected to cost A$1-$1.3 billion ($704-$916 million) in upfront capital and lead to all-in sustaining costs going from $1.05/Ib ($2,315/t) in the sublevel cave operation to $0.90-$0.95/Ib during block cave operation.

The plan would see OZ Minerals access the higher-grade bornite mineralisation first, via the top-down sublevel cave, followed by a bottom-up block cave, OZ said.

Mine expansion and transition to a block cave would require adjustment to the location of future underground infrastructure below crusher station two, including a change in orientation of the decline, conveyor and ventilation, OZ said. In the current operation plan, this is not due for installation until after 2021.

The materials handling system and crushing infrastructure would require additional drive motors and a faster conveyor system to hit the new 10-12 Mt/y capacity, while there would need to be upgrades to the primary and secondary ventilation systems; electricity and communications infrastructure; and water supply, dewatering and underground facilities.

In terms of the process plant, there would need to be either a new parallel processing plant installed or an upgrade of the current sublevel cave processing plant.

OZ Minerals CEO, Andrew Cole, said: “The Carrapateena Block Cave Expansion work showed the conversion to a block cave to be the most value accretive next step for the Carrapateena resource and conceptually for the entire province, as it potentially enables a series of future add-on block caves, which themselves will now be the subject of a Carrapateena Life of Province Plan scoping study.”

He said the sublevel cave construction project remained on schedule for first production later this year, with ramp up to full production of 4.25 Mt/y taking place over the following 18 months.

The company will now move onto a prefeasibility study for the block cave expansion plan, which is expected to be completed by mid-2020.

Factoring in the scoping study results increases life of mine tonnes from 84 Mt at 1.8% Cu and 0.7 g/t Au, to around 145 Mt at 1.2% Cu and 0.5 g/t Au over a 20-year period.

Mining3 to expand rock bolt safety testing for underground mines

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Mining3 Technology Leader, Sam Spearing, says developing more effective rock bolt designs that not only take tension into consideration but also bending and shear (guillotine) could significantly improve safety.

In addition, the basic rock bolt could serve a greater purpose by showing principal stress directions in the immediate rock, which could be used to better calibrate computer simulations, according to Spearing.

“Rock bolts have formed part of the underground mining environment since the 1890s and are effective in stabilising and controlling the immediate roof and ribs (sides) of tunnels.

“Although they are an integral part of the underground mining support structure, very little is known about the actual load distribution along a rock bolt. Current design practice only considers the axial load capacity of the rock bolt yet they are subjected to combinations of axial, shear and bending, in situ.”

Rock bolts are generally exposed to a combination of shear, bending and tension that can cause the bolt to deform with increasing displacements along and across faults, joints and beds, potentially leading to failure, Spearing said. In spite of these combined effects, only tensile capacity is currently considered in design and testing.

Adding to this design oversight, tensile capacity isn’t the weakest performance link. Shear capacity, on the other hand, holds roughly 70% of tensile strength, which leads to support designs that tend to overestimate the rock bolts effectiveness, according to Spearing.

Mining3 is currently working on a project to:

  • Understand in-situ rock bolt performance;
  • Develop computer models that provide a more accurate and visual representation of how rock bolts perform underground;
  • Determine the principal stress directions close to excavations, and;
  • Create instrumented rock bolts that can measure load along the length.

Spearing said: “A broader outcome of this project will be the ability to remotely monitor the loading on rock bolts in real time from a control centre on the surface. Providing this level of visibility would allow miners to better predict failures and avoid them, which could be a game changer in the field of rock related safety in underground mines.”

A separate follow-up project is already approved and funded to design a specific instrument to measure total strain in the immediate roof or rib, according to Spearing.

Current technology being tested in conveyor monitoring has a similar application in which, through the use of fibre optics, it is able to pick up signature acoustics that indicate movement related to stages of failure in rollers, according to Spearing. “In the case of monitoring rock bolts, if fibre optic cable is adhered on or within the rock bolt, it will enable the detection of ground movement. Data is analysed, interpreted and presented from an offsite control centre and could indicate where and when tunnel failure may occur,” he said.

 

First Muckahi mining system on site in Mexico, Torex Gold says

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At the same time as reporting record gold production for 2018, Torex Gold has provided an update on its innovative in-development Muckahi underground mining system.

The company recovered from a blockade at its ELG mine, in Mexico, which affected operations earlier in the year, to produce 353,947 oz of gold in 2018, with 96,316 oz of that coming in the December quarter. Torex guided for production of 430,000 oz in 2019.

In tandem with these results, the company’s President and CEO, Fred Stanford, talked up the company’s Muckahi concept, an alternative to established underground mining processes that, Torex says, can create a more continuous mining process able to accelerate return on investment.

Stanford, who is credited as the originator of the technology, said in the company’s 2018 financial report: “If proven successful in 2019, the Muckahi technology will reduce the costs of future underground mining on the Morelos property (which includes the ELG and Media Luna assets) and will provide us with a competitive advantage when bidding on potential acquisitions and pursuing other options for commercial deployment.”

He said the testing programme for the Muckahi technology was expected to be completed in 2019, with the first of four Muckahi machines on site in Mexico. “We anticipate breaking rock with it in the next couple of months,” he said, adding that as the other machines arrive, the company would incorporate them into the test programme.

The planned use of the Muckahi system, which is also being developed with help from MEDATECH, in the most recent preliminary economic assessment for the Media Luna project saw the after-tax internal rate of return jump from 27% to 46%.

For 2019, Torex’s Muckahi plans include:
• Development on the level;
• Development on a 30° down-ramp;
• Long-hole open stope fragmentation to 95% passing 400 mm, and;
• Mucking a long hole open stope with a slusher.

Remote operations could be the way forward at Westwood, IAMGold says

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IAMGold says it is looking to remotely-operated machinery to battle the challenging ground conditions being experienced at its Westwood underground gold mine in Quebec, Canada.

Westwood produced 28,000 oz of gold in the December quarter, 3% lower than the same period a year ago, the company said in its 2018 financial results. This was primarily due to lower head grades.

“The lower grades reflected mining activity that sequenced through lower-grade stopes as part of the mine plan. Head grade, excluding marginal ore, for the fourth (December) quarter and year ended 2018 was 6.78 g/t Au and 7.16 g/t Au, respectively (2017: 8.01 g/t Au and 7.8 g/t Au),” IAMGold said.

Underground development for the year ended 2018 was 10,600 m, averaging 29 m/d and comprised of 10,100 m of lateral development and 500 m of vertical development, according to the company. Underground development continued in the December quarter to open up access to new mining areas with lateral development of approximately 2,500 m, averaging 27 m/d.

The company said: “During the quarter, development continued to focus on the ramp breakthrough on level 132, while respecting safety protocols in place for mining in areas where seismicity is present.”

In line with these safety protocols, three units of bolting equipment designed to manage seismic exposure were received during the December quarter, IAMGold said.

The company said it expects production at Westwood in 2019 to be in the range of 100,000-120,000 oz as mining and development activities continue to progress.

Yet, in maintaining the company’s safety protocols at the underground operation, IAMGold said it was expecting to commission additional equipment at Westwood, in 2019, capable of operating “remotely in areas with challenging ground conditions”.

IAMGold is currently working on reviewing the mine plan at Westwood, its only underground operation, and expects to publish updated development guidance in the December quarter.

Sandvik introduces new ‘intelligent’ LH621i underground LHD

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To expand its existing “intelligent” offering, Sandvik has introduced its second i-series loader, the Sandvik LH621i.

The LH621i is the loader of choice for rapid mine development and large-scale underground production, according to the company, and is a matching pair with the previously introduced 63-t payload Sandvik TH663i truck.

Sandvik said: “The Sandvik LH621i sets the industry standard in the 21-t underground loader range.”

It has been built on technology inherited from the Sandvik LH621, and now enters the market equipped with further improved features, according to the company.

“With superior hydraulic power for fast bucket filling and drivetrain power for high ramp speeds, the Sandvik LH621i is designed to quickly clear tunnel headings for rapid advance rates,” Sandvik said. “Engineered with operator and maintenance personnel safety in mind, the rugged loader offers long component lifetimes and low costs per tonne.”

The Sandvik LH621i features the latest Sandvik Intelligent Control System and My Sandvik Digital Services Knowledge Box™ on-board hardware as standard, providing product health monitoring and faster troubleshooting, according to the company.

The equipment has been designed automation ready, enabling the installation of Sandvik’s AutoMine® installation as a retrofit in just a few days. To improve comfort and productivity in manual operation, improvements have been made to the operator’s compartment, as the Sandvik LH621i features a more spacious and ergonomic cabin with increased visibility and 7 in (17.8 cm) touch-screen colour display.

“In the engine compartment, a fuel efficient 352 kW Stage II/Tier 2 engine deliveries powerful thrust for fast bucket filling and high-speed tramming for high productivity. A new, more powerful 375 kW Tier 4 Final/Stage IV low emission engine option is available with the use of ultra low sulphur diesel fuel,” the company said.

The diesel engine brake in the Stage IV/Tier 4 Final engine provides better control of vehicle speed downhill, minimising brake and transmission overheating and brake wear. Further, SHARK™ ground engaging tools are available on a wide range of bucket sizes, optimised for loader productivity and extended bucket service life.

Olli Karlsson, Product Line Manager, Large Loaders, Sandvik Mining and Rock Technology, said: “The new Sandvik LH621i competes in a space of its own. This new 21-t capacity loader truly represents a new breed of productivity and emphasises Sandvik’s capability to develop robust and efficient underground load and haul equipment.”

Sandvik’s i-series loader and truck family now includes two loaders and three trucks – the Sandvik LH517i, Sandvik LH621i, Sandvik TH545i, Sandvik TH551i and Sandvik TH663i.

Caterpillar’s R1700 underground LHD starts to prove its worth

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Caterpillar’s recently launched Cat® R1700 Underground Mining Loader has proven its high productivity and efficiency in extended field trials and in-production studies, the company says.

The completely new design R1700 carries a size-class-leading payload of 15 t, 20% more than its predecessor, yet maintains the dimensions of the R1700G.

“A recent head-to-head study and multiple field trials show that the machine surpasses its payload advantage in faster truck loading and more productive load-and-carry operations while delivering 21% less fuel consumption per hour in a recent study,” Cat says.

The R1700 comes with cycle time advantages over its predecessor through fast bucket loading. This has been enabled through high digging forces and a new traction control system that limits tyre slip when the bucket enters the pile.

“The result is fast loading, good bucket fill factors and reduced tyre wear. Excellent machine balance and a new electrohydraulic braking system aid load-and-carry cycles,” Cat says.

Fuel efficiency is improved through on-demand adjustment of the cooling fan and the hydraulic system, as well as the proven efficiency of the Cat C13, six-cylinder engine, according to the company. The engine is turbocharged and air-to-air aftercooled, and it produces 269 kW in standard configuration and 257 kW in EU Stage V compliant form.

The engine is available in three different emissions configurations – Cat Ventilation Reduction, US EPA Tier/EU Stage IIIA, and EU Stage V – tailoring the R1700 to the mine’s ventilation needs. Aftertreatment for the Stage V engine configuration is chassis mounted for convenience and includes a Diesel Emission Fluid tank sized to match the 12-hour capacity of the fuel tank.

The R1700’s productivity is boosted even further with multiple subsystems for fast technology implementation.

“Optional Autodig helps new operators be productive the first day and reduces fatigue for experienced teams. Remote machine health monitoring, payload operating technologies are available via MineStar™ Command for underground,” the company says.

During the load or dump cycle, the harder the operator pushes the controls, the faster the machine responds. The steering system is pilot-controlled to provide a more precise feel for the operator during manoeuvres in tight places.

“Ride control is now fully integrated into the hydraulic system and engages automatically as the machine goes above 5 km/h. Electronically snubbing the cylinders protects them and provides greater operator comfort,” Cat says.

The R1700 has auto retarding which is hydraulically actuated. The system comes on automatically when the operator’s foot is lifted from the throttle, with cycle times improving as operators gain confidence and become more comfortable on downhill grades at faster speeds.

For easier maintenance, the R1700 features several components that have modular designs – they can easily be removed and replaced.

In addition to modular components, all filter and key service points have been grouped into a centralised section on the cold side of the engine. The radiator guard swings open for ground-level access to the radiator, and oil coolers and the batteries are easily accessed just under the centralised service location.

For the entire underground loader line, Caterpillar now offers Bolt On Half Arrow ground engaging tools (GET) for bucket edges. The system is designed for high abrasion applications where weld-on GET experience high wear rates.

“With a proven and reliable retention system, the bolt-on GET offer more wear material than standard weld-on GET, and the bolt-on design enables fast and easy removal and replacement.

“Despite additional wear material, the low-profile front edge eases pile penetration and promotes fast bucket loading,” Cat says.

Master Drilling aims for new status as mining TBM specialist

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Master Drilling, through subsidiary Master Tunnelling, is not trying to re-invent the wheel with its mobile tunnel borer (MTB) concept, but that doesn’t mean to say the application of such technology will not have a big impact on the underground mining space.

The company, up until recently thought of as a raiseboring specialist, is up against stiff competition in the horizontal mechanised cutting sector. It has Epiroc and its Mobile Miner, Sandvik and the MX650, Caterpillar and the RH55 and Komatsu (Joy) and its DynaMiner to contend with, all of which have been trialled in underground mines.

But, the South Africa-based company is hoping its contracting model, tunnelling partner, modular design and operational flexibility will put its MTB in the lead.

Mining companies on a global basis have been looking for a mechanised, continuous alternative to the labour intensive drill and blast batch process for decades.

Several companies have tried to cater to this need, but no one technology has provided the ‘silver bullet’ as of yet.

Still, the drive to get personnel out from harm’s way, the need to improve tunnelling quality with an increasing number of block cave developments and decrease the payback period for what can sometimes be multi-billion dollar investments has resulted in the latest slate of horizontal cutting machines.

Master Tunnelling has partnered with Italy-based tunnelling expert Seli Technologies to launch its new product and IM recently visited a quarry site just outside of Rome where the first MTB is being assembled and tested.

On site, Koos Jordaan, Executive Director of Master Drilling, talked IM and a host of other interested visitors from mining companies through the machine specifics.

“To reduce risk, we stuck to proven cutting technology,” Jordaan said, pointing to the cutter head design in a schematic within one of the quarry’s temporary offices. “The concept is not so radical, it is more incremental based on tunnel boring.”

The full-face cutter head is made up of 17” disc cutters, which are conventional from a TBM perspective, but are made up of five separate segments. This cutter head, like the majority of the 240-300 t MTB, is designed to be broken down for transport.

The MTB is made up of four track-mounted units containing various parts – the cutter head and bolting section is up front, followed by the transformer and 300 m capacity water and electrical reels on the third unit, and a 14 m3 capacity storage bunker and discharge system on the fourth unit.

The units are also equipped with conveyors that transport the mucked material along the machine.

These can be individually broken down and potentially shipped in 10-12 20-foot containers, according to Jordaan.

This modularity should enable Master Tunnelling to access existing mines with decline infrastructure and to start tunnelling from an underground location, as well as to work on such infrastructure from the surface.

The full-face cutter head is capable of a 1 m advance stroke and can cut rock in excess of 300 MPa compressive strength. It can also be remotely controlled by an operator, reducing exposure to the face.

The MTB comes with 5.5 m diameter cutter head or 4.5 m diameter cutter head. The former is for declines, portals, haulages, inclines, ramps, ring roads, etc, with the latter allowing for excavation of drives and contact tunnels.

Master Tunnelling is aiming for an advance rate of 6-9 m/d in 200-250 MPa rock, but is not discounting the possibility of a higher rate should the additional mucking transport systems behind the 23 m (4.5 m diameter MTB) or 31 m (5.5 diameter MTB) machines be able to keep up.

Jordaan admits going past the 300 MPa threshold was likely to lead to advance rates dropping off by as much as a third, but is adamant the machine has the capability to cut through such rock.

All of this cutting takes substantial amounts of power, which the four hydraulic motors have in abundance. The MTB has 1,300 kW of installed power and a 1,600 kVA on-board transformer that more than covers the machine’s requirements.

Behind the cutter head, hydraulically-powered side grippers ensure the machine can thrust forward and start cutting, while there is a finger shield that both protects workers and allows for a support drill to install cable bolts for ground support.

Master Tunnelling envisages at least three personnel being required for full continuous operation in most setups.

Driving on a flat roadway

As Master Tunnelling points out, “a round profile tunnel is not ideally suited for vehicles that require a flat driving surface, such as most trackless mining equipment.”

This is where a articulating tail conveyor at the end of the fourth tracked unit – containing the 14 m3 storage bunker – evenly distributes 3-5% of the cut material. This should provide the sort of flat driving surface trucks will need to come in and pick up the material.

Master Tunnelling has some form here, too. Its Master Drilling parent company carried out a horizontal raisebore drive of 180 m length and 4.5 m diameter in a kimberlite pipe at Petra Diamonds’ Cullinan mine in South Africa recently. A flat driving surface was created by using a similar solution to the one the company has devised for the MTB.

There are also a few other features worth flagging.

The MTB is able to operate on a 12° incline/decline, has a 30 m turning radius and can be dismantled and brought back to surface after a project is complete.

The latter is different from the bulk of conventional TBMs where, after use, they are buried underground never to be used again.

Master Tunnelling is also taking safety seriously with the MTB. Not only is it shielding bolting operators from potentially hazardous situations above their heads all the way from the cutting face, it is also installing gas detection, proximity detection and fire suppression systems on the units. An operational monitoring system, meanwhile, ensures the full-face cutter head is advancing as planned and the accompanying units are tracking as they should be.

Master Tunnelling anticipates a four-hour maintenance period for the MTBs every 24 hours based on a three, eight-hour shift pattern. During this time, the disc cutters can be replaced and the dust suppression and collection system can be checked.

The company also envisages this time being used for drilling a 30-50 m probe hole in advance of the MTB. This would be drilled through an opening in the cutter head and provide integral information about the water and gas levels of the approaching rock.

The MTB doesn’t do away with drilling and blasting altogether. To initiate cutting, the machine requires a rounded profile side wall to grip and thrust to take it forward. This requires a starter frame to be installed in advance of the drive, which can be put in position with a 15 t capacity wheel loader with appropriate manipulator attachment.

The frame requires a starting chamber 6.5 m high, 8 m wide and 12 m deep excavated by conventional drilling, blasting and scaling.

In an undercut level for block caving, this preliminary batch phase would only form a “small part of the excavation required”, Master Tunnelling says.

In addition to considering the setup requirements for the MTB to start operation, it is also worthwhile to look at what will follow the machine in terms of loading and hauling the excavated material.

This is where the bunker backup unit positioned at the end of the four tracked units proves useful, acting as a storage facility to allow truck changeover to take place behind the MTB when one truck is fully loaded and another truck comes in. This allows for continuous operation of the MTB incorporating a batch haulage system.

On long, straight advances there is also the possibility of using mobile conveyors for haulage, however the company thinks there will be less of these applications given the MTB’s major strengths are developing tunnels with a curvature or on a decline/incline.

Contractor advantages

In the battle for a market leading, horizontal, mechanised cutting technology, Master Tunnelling has a few advantages over its much bigger rivals in the mining space.

One: it is a contractor, meaning it is not asking customers to invest in this capital-intensive equipment. Instead, it will be contracted by the client to provide the MTB and associated equipment required for logistics and material handling.

Two: It has a partner in Seli Technologies that has carried out more than 1,000 km of tunnelling excavations and has been involved in mining work before (it excavated an 8 km long, 4.2 m diameter tunnel for Anglo American at Los Bronces, in Chile, back in 2009).

Three: It is offering something that is modular, can be broken down and assembled underground, and can be relocated from one project to the next.

Also, Master Tunnelling is offering the ability to turn around corners and keep tunnelling with the MTB, which could be particularly useful when tracking complex, or faulting mineralisation. It could also come in handy should the MTB encounter particularly hard to bore rock.

The concept phase of the MTB only started in April 2017 and only one MTB has so far been manufactured. So, for the right partner, there is the chance to get in early and to advise on their customised requirements.

Master Tunnelling is clearly thinking to the future in this regard, with the bulk of the MTB hardware being ‘automation-ready’.

Even though the set up at the quarry in Italy is to test basic functionality – cutting 10-20 MPa rock for 50 m and carrying out a 30 m turn – it has provided interested parties a chance to consider what the machine could do for their own operations.

Once it has optimised the setup time and demonstrated what it can do in some fairly competent rock underground, the wider mining community may start to further appreciate the MTB and what Master Tunnelling is offering.

Muckahi Mining System set for underground testing in Q1: Torex Gold

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The new underground mining concept put forward by Torex Gold’s President and CEO Fred Stanford is gaining some traction at the company’s early-stage Media Luna project in Mexico, with the new technology potentially able to cut upfront capital requirements, reduce operating costs and decrease the time to commercial production.

IM reported on the highlights of the latest preliminary economic assessment in an earlier story, which showed the after-tax IRR going from 27% to 46% using the Muckahi Mining System (MMS) concept. But, the filing of the latest technical report has brought out some more details.

The report states on MMS: “The system challenges the status quo in many ways with the goal of establishing more efficient and cost effective alternatives to established mining processes.”

The MMS requires the use of a one-boom jumbo, service platform, mucking machine and tramming conveyor to create a more continuous mining process that can accelerate return on investment. It also significantly reduces the ventilation needs in underground mines by using conveyors as the main transport solution, playing into the mine electrification theme that is gaining traction.

Stanford, who is credited as the originator of the technology, explains the design rationale in the report:
“The production system in a mine is effectively a serial set of processes, with the ultimate objective of delivering rock, at specification, to the processing facilities. Each process step will have a primary design objective of either transformation, transport, or storage. In some processes there will also be inadvertent, non-design, transformation. This inadvertent transformation is generally not a desired outcome (ore pass slough, oxidation, etc).

“It is quite common for the ‘rates’ or ‘availability’ of processes in a serial set of processes to be out of alignment/coordination with each other. When this is the case, the productive capability of the entire system is reduced.

“To increase the productive capability of the system, designers frequently insert storage processes between transformation and/or transport (T&T) processes. These storage processes serve to reduce the inter-dependence between T&T processes and thereby increase throughput. This can be an effective design feature to maximise output, but it is expensive.

“In an underground mine these storage facilities, whether they are for rock or supplies, must be excavated and equipped, which consumes capital. They frequently also require re-handling, which consumes operating dollars. A design objective for Muckahi was to eliminate the need for storage processes by finding ways to bring into alignment the rates and availability of the entire set of T&T processes.”

He continues: “If the quality (size) of the rock product from the primary blast is not adequate for downstream processes, then a secondary sizing process will need to be added to the ‘set of processes’. Having ore-passes in the mine design will also force a requirement for a secondary sizing process. This is due to the uncontrolled size of the wall rock that, over time, will slough into, and dilute, the ore product.

“Secondary sizing processes, particularly underground crushers, are expensive and time consuming to build and expensive to operate. A design objective for Muckahi is to eliminate large size secondary size reduction processes and just deal with minor oversize management with mobile rocker breakers or ‘chunk’ blasting.”

To materially reduce the capital, operating cost, and mine build schedule, the MMS design approach sought ways to reduce the number of process steps and make the remaining process steps more efficient.

This involved eliminating secondary sizing processes that required ‘constructed’ facilities such as a crusher station – thereby eradicating the need for ore passes – cutting out all storage facilities, and replacing the current logistics model of one-way traffic in large tunnels, with two-way traffic in tunnels half of the size.

Stanford said the MMS has been able to achieve all of these requirements on a conceptual level by using five solutions:

  • Blasting rock down to a smaller size – if the rock is to go directly onto a conveyor, then the product of the primary blast must be in the range of 95% passing -400 mm. Achieving this specification is not a challenge for ‘short hole’ primary blasts, such as used in development or cut and fill production mining methods. For ‘long hole’ production methods, it will require much tighter control of drilling procedures, explosives placement, and detonator timing;
  • Twin roof (back) mounted monorails in all tunnels – this technology from the European coal industry solves several of the design challenges. It provides a stable platform for ‘long and skinny’ loads, allows climbs up steep 30° ramps and two-way traffic (one rail for inbound traffic and the other for outbound). SMT Scharf Group and Becker Mining Systems are two companies currently supplying these systems to the mining industry;
  • A new transport concept named a ‘Tramming Conveyor’ (pictured) – this machine deals with the ‘first mile’ from the face/drawpoint, when straight lines for conventional conveyors are not an option. The conveyor is end loaded at the drawpoint until the belt is fully loaded. The belt then stops ‘turning’ and the whole unit drives away on the outbound rail to the discharge point. At the discharge point, the belts starts turning again and discharges its load (conveyor-to-conveyor transfer). The unit then switches to the inbound rail and returns to the drawpoint. While it was away from the drawpoint, other units have been loaded – hence, one of the benefits of two-way traffic;
  • Ramps at 30° instead of the conventional 7.5° – the rubber tyres on conventional equipment lose traction on gradients that are much steeper than 7.5°. The back-mounted monorails remove the need for rubber tyres, hence the ability to steepen the ramps to the 30° gradient that can be handled by the cog drive system;
  • Twin tunnels in waste – the tunnels in a Muckahi mine are half the volume of the tunnels required for a 50 t truck in a conventional mine. Half the volume means less rock to remove, less ground support, fewer holes to drill and load in the face, etc. This means they can be driven much more quickly. In a Muckahi mine, there are also no muck bays to be driven, which reduces metres by approximately 20%. The net effect is that excavation rates in a 4 m x 4 m tunnel should be two to three times faster than in conventional tunnel of 5.5 m x 5.5 m.

Torex said the concept is now shifting to the underground testing phase, with manufacturing of the first of the prototype machines underway in partnership with Medatech Engineering Services out of Canada. This could see the first trials underground at the company’s ELG mine in the March quarter.

In summary, the key expected benefits of Muckahi are:

  • Continuous muck handling system and the elimination of re-handle and storage;
  • All-electric operation and significant reduction in ventilation requirements;
  • Ability to travel on ±30° (58%) slope and major reduction in both permanent and operating development;
  • Ability for bi-direction travel in 4m x 4m tunnel.