Tag Archives: 3D laser scanning

CSIRO maps out laser scanning solution for underground coal mines

New real-time underground 3D mapping technology developed by CSIRO can be used to locate, steer and navigate equipment and vehicles in volatile, methane-rich underground environments, according to Australia’s national science agency.

ExScan technology, being trialled by Glencore, as well as five other mining companies, has a laser scanner and associated software capable of generating real time 3D maps of tunnels, walls and cavities underground where global positioning system (GPS) cannot penetrate. These maps can be used for locating, steering and navigating equipment and vehicles.

Arguably, the real innovation in CSIRO’s new underground mapping technology is not the smart laser-based scanner, but the container in which it sits, CSIRO said.

“The enclosure has been certified to International Electrotechnical Commission ‘Ex d’ standards for use in volatile, methane-rich underground environments such as coal mines,” the agency said.

“That means it has been designed to prevent the electronic equipment it houses sparking an explosion.”

CSIRO Electronic Engineer and ExScan Project Lead, Peter Reid, said: “Nothing can go underground in a coal mine unless it’s certified to be in that environment. You can’t even take an aluminium can; it’s a potential spark hazard if it gets crushed by a vehicle. So getting electronics down there is a tricky process.”

The problem is that explosive gases such as methane penetrate equipment and any failure of electronics that causes a spark could lead to a fiery disaster.

The solution outlined in the Ex d regulation is not to contain explosions, but to prevent them from happening in the first place. That’s achieved by designing the container to ensure any spark would have to travel such a long way to encounter sufficient gas to trigger an explosion and, by that time, it will have cooled below the ignition point, CSIRO said.

Looking to longwalls

Many members of CSIRO’s ExScan development team spent years working with industry on the Australian Coal Association Research Program-funded project that developed the successful LASC longwall automation system.

A major driver behind automating coal mining is to remove people from the dusty, hazardous environment near the coal face, but even the LASC automated equipment occasionally needed hands on human measurement to guide it through trickier parts of the coal seams.

The idea behind ExScan was to provide images that could be used to make those measurements automatically, CSIRO said.

“This technology provides us with information that cameras on their own can’t,” Reid said. “It allows us to measure in 3D anything we see, as if we were there.”

The LASC ExScan is a 3D scanner, housed in an explosion-proof casing, that can map tunnels, voids and cavities in real-time underground.

What emerged looks a little like a 25 cm-high version of Star Wars character R2-D2 – with a steel base into which a polycarbonate dome screws, CSIRO said. The laser sits under the transparent dome and scans through it. To get outside into a volume of gas, any spark generated would have to work its way through a narrow sawtooth path formed by the screw thread and, in doing so, would lose most of its energy.

Should the scanner malfunction or the container become scratched or damaged, it can be swapped over in a matter of minutes, because the dome just screws off, CSIRO explained.

The team invested a lot of time in computer modelling to come up with a dome that was just right for injection moulding. That makes the ExScan devices relatively inexpensive to manufacture, according to CSIRO.

“In fact, they are affordable enough for a line of 40 or 50 to sit behind the mining equipment along a longwall face of between 400 and 500 m in length, providing real time updates of the condition of the wall,” it said. “At 10 metres apart, the devices are close enough to allow redundancy – their scans overlap, which means that if one fails, its absence can be covered by others on either side to ensure overall reliability.”

Removing people from the coal face

According to Glencore Technology Superintendent at Oaky North mine, in central Queensland, Lauris Hemmings, the images they generate can be used to determine and sort out coal flow blockages on the conveyor system under the shearing equipment and to help align and steer the shearers themselves.

“It’s a fantastic tool,” Hemmings said, “an ever-evolving piece of equipment that takes risk management to even higher levels.”

The mine is already hoping ExScan can be used to navigate the higher risk areas of the mine, taking employees away from the coal face.

But the applications are broader. The scanners can be mounted in any orientation – even upside down – and on moving machinery and vehicles. This means they can be used to map whole mines, and potentially for vehicle navigation, CSIRO said.

The containers themselves can be employed for other electronic purposes, such as housing camera systems, and are already being marketed separately by Eaton Industries.

In addition to Glencore, the LASC ExScan system is being trialled by five other Australian mining companies, as well as by companies overseas.

“The Chinese coal industry has become so interested that it has invested the resources for a couple of engineers to develop skills to deal with the large amount of data generated by the scanners,” CSIRO said. “The feedback from all this activity is allowing the CSIRO team to develop new features for the scanner.”

CSIRO is now determining next steps to commercialise the ExScan system.

Weir Minerals Africa enhances offering with simulation, modelling software

Digital design and simulation technology tools are enhancing Weir Minerals Africa’s solution offering to customers, the company says, allowing insights into upstream and downstream improvements that optimise mineral processing.

“With our focus firmly on integrated solutions, we are increasingly able to leverage technology to benefit our customers,” Christian Stehle, Head of Engineering at Weir Minerals Africa, says. “This applies not only to how we design our product solutions, but how we help customers to examine their whole process.”

Simulation and modelling software tools are key enablers in this quest, according to Stehle. “They give the Weir Minerals Africa engineering team the power to use computational fluid dynamics, for instance, to model the behaviour and flow of liquids and gases,” the company said.

Stehle added: “In addition to analysing our own equipment, we can also understand more about what happens upstream of our equipment. Understanding material flow at various points of the customer’s plant process is vital to optimising how our equipment works.”

By the same token, discrete element modelling software simulates material flow of solid particles. This allows users to model the flow of material through feed chutes and into Weir’s crushers and vibrating screens. The analysis software in this field – like everywhere – is constantly advancing, providing an increasingly detailed understanding of material behaviour, according to Weir.

“Using technology tools like these, we put our mechanical and metallurgical expertise at the disposal of the customer,” Stehle says. “It gives us the ability to make a scientific assessment of where their plant challenges lie, while also giving us the power to develop specific solutions to solve the customer’s problems.”

Weir said: “The extensive suite of the company’s mineral processing products can then be employed to address the challenges that are identified using these technology tools.”

Stehle says the value of tools like 3D laser scanning, which can be used to quickly and accurately map a customer’s plant layout and dimensions. The scanned data is then integrated with Weir Minerals Africa’s computer-aided design software to design solutions that fit into the existing plant footprint.

“We can then provide solutions that are engineered to order, with precision that ensures we get it right the first time,” he says. “This means quicker installation and commissioning, so there is less downtime for the plant.”

Fast-evolving software also facilitates the application of finite element analysis for stress analysis in structural design.

As Weir Minerals Africa extends its offerings in comminution, the team puts this technology to work in designing ancillary support structures around its equipment. This includes the design and construction of modular plants for crushing, screening and sand washing.