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Drones and Aerial Operations Emergency Equipment WHAT'S NEW IN AUSTRALIAN MINING

CSIRO Hovermap looks to make mines safer

drones in mining CSIRO project
The new mining drone technology will assist safety by reducing personnel access to areas where unsafe conditions exist.

The Commonwealth Scientific and Industrial Research Organisation (CSIRO) latest project is the Hovermap product, a system that uses autonomous drones in mining to investigate underground areas to determine their suitability for mining operations. The technology was developed by start-up Emesent, founded by two former CSIRO members, and aims to improve the accuracy of underground mapping, where systems like GPS are ineffective, and reduce risks by removing human workers from potentially dangerous subterranean areas.

The CSIRO has raised A$3.5m through its Innovation Fund, with money coming from investors Main Sequence Ventures and ACAC Innovation, to further refine the system for use in underground mines, and expand its influence beyond the five countries where it has already been deployed.

Emesent’s CEO and co-founder Stefan Hrabar has worked with the International Forum for Aviation Research, while CTO and co-founder Farid Kendoul has worked with NASA; between them, they have 28 years of experience in working with drones and start-up companies.

In 2017, the company completed a number of successful test flights, including a trial at South32’s Cannington mine in January, and the world’s first autonomous beyond line-of-sight drone flight in September, when a drone flew through Northern Star Resources’ Jundee gold mine in Western Australia, 600m below the surface. Emesent has also used the drones to participate in the US Defense Advanced Projects Agency’s Subterranean Challenge, which tests solutions for mapping and searching underground areas.

The drones fly autonomously and collect a range of information, such as the shape of a cave system, using a process known as simultaneous localisation and mapping (SLAM). SLAM enables drones to construct 3D images of their environments using a system called LiDAR, where the drone fires laser light at nearby structures, and measures how the light is reflected by the surfaces it hits. This process lets the drones produce accurate renditions of cave systems without the need for external services, such as GPS location, which is often ineffective underground.

The Hovermap drones are also able to record levels of gases and identify geological features and can take photos and record videos of cave systems to aid in the construction of cave diagrams.

One of the most impressive features of the technology is that the drones use the same data they collect to construct images of caves to locate themselves within the caves, a system that improves the quality of both sets of data. By using SLAM for both navigation and location, both elements are improved; the drones are reliant on collecting accurate data to remain in the air, which means they can stay in the air for longer, and ultimately collect more data to construct more accurate images of the cave systems.

Emesent’s drones also offer significant safety benefits to workers. By removing the need for humans to enter unfamiliar underground areas to complete mapping work, workers are no longer expected to work in these potentially dangerous areas. The high quality of the drones’ recordings also safeguards future mining operations from the kind of mapping errors that contributed to the 2002 Quecreek mine disaster in the US, where nine miners were trapped after breaking into a passage they did not know was there, and accidentally flooding the mine.

The Hovermap drones are a significant upgrade to conventional cavity monitoring systems (CMS), which are typically used to map underground areas. CMS solutions involve placing a camera at the end of a pole, which is then inserted into passages. While this enables workers to record still images and videos from areas inaccessible to human workers, the technology is limited by physical constraints such as the length of pole and dimensions of the cave, and few CMS cameras are fitted with LiDAR technology. CMS images are also affected by shadows, as they build up images from photos and videos recorded at the site, while Hovermap’s SLAM system eliminates shadows from final images.

Emesent plans to use the CSIRO funding to take the drones to market, after a successful pilot scheme involving companies based in Australia, Canada, China, Japan and the US. The pilot scheme was backed by the Australian Science and Industry Endowment Fund, which funded the production of eleven drones, three for its own use, and eight for use by the early adopters.

The study was used to refine the technology behind the system, and in particular develop the drones’ autonomous capabilities from an early warning system alerting a human operator to the proximity of obstacles, to the fully-automated navigation system the drones now use. While Emesent intends to sell the drones as complete products to mining companies in the short term, it may push for further funding to license and sell the SLAM software itself to customers who want a more tailored system in the long term.

“The investment will give us the opportunity to build out our team from seven to 25, and make Emesent a global leader in drone autonomy and automated underground data collection and analysis,” Hrabar said in a press release. “The data we gather improves a mine’s productivity and provides a better understanding of conditions underground, all without sending surveyors and miners into potentially hazardous areas.”

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AMSJ Nov 2021