Mine Digitalization: Automation and Collision Avoidance by Radar-tag Localization and Radar-scan Mapping (UPNS4D+)

Motivation Mine digitization is a consequent approach to establish industry 4.0 / IoT related mine operation models based on various dimensions: flexibility, coverage, real-time capability and analytics. Networking technology, wired and wireless, can be easily deployed large scale. Miniaturized sens...

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Main Authors: Winkel, Reik, Rabel, Matthias
Other Authors: TU Bergakademie Freiberg, Geowissenschaften, Geotechnik und Bergbau
Format: Others
Language:English
Published: Technische Universitaet Bergakademie Freiberg Universitaetsbibliothek "Georgius Agricola" 2018
Subjects:
Online Access:http://nbn-resolving.de/urn:nbn:de:bsz:105-qucosa-231178
http://nbn-resolving.de/urn:nbn:de:bsz:105-qucosa-231178
http://www.qucosa.de/fileadmin/data/qucosa/documents/23117/10.UPNS4D%2B_RTM2017-10_1b.pdf
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spelling ndltd-DRESDEN-oai-qucosa.de-bsz-105-qucosa-2311782018-03-23T03:26:50Z Mine Digitalization: Automation and Collision Avoidance by Radar-tag Localization and Radar-scan Mapping (UPNS4D+) Winkel, Reik Rabel, Matthias Real-Time Mining Konferenz Real-Time Mining Conference ddc:624 Bergbau Bergwerk Markscheidekunde Geoinformation Prospektion Motivation Mine digitization is a consequent approach to establish industry 4.0 / IoT related mine operation models based on various dimensions: flexibility, coverage, real-time capability and analytics. Networking technology, wired and wireless, can be easily deployed large scale. Miniaturized sensors, thus can be placed anywhere. Laser technology has been successfully used for more than a decade in the manufacturing industry. However, due to restrictions found in challenging heavy industry environments, such as dust, fog, rain or snow, laser technology can only rarely be found in mining applications. At the same time, technology-supported geometrical environmental scanning is essential for the control of mining machines. GPS in open pit mining is the state of the art technology for machine allocation and dispatch, whereby an underground equivalent is still missing. Because of this technology gap, many machines are frequently operated beyond their original design boundaries, and not according to the production planning which may result in significant safety impacts and collisions. Recent breakthroughs in radar technology both in 2D/3D passive scanning as well as /3D Active localization is bound to trigger a revolution in mining. In close collaboration with major universities, radar technology has been developed to mature and ruggedized industrial sensors by indurad. The public funded project “UPNS4D+” which stands for “Underground 4D+ Positioning, Navigation and Mapping System“, funded by BMBF (FKZ: 033R126), focuses on fully autonomous operated vehicles, including navigation, orientation, collision avoidance by driving autonomously around obstacles whether detected with the radar-tag system or by environmental Radar-scan. Asset and Personnel Localization Radar-tags are suitable to detect any tagged object or person. Vehicle based Radar-radios are used to measure distances and angles to radar-tags, relative to the vehicle. Any other machinery, person helmets, equipment can be tagged and thus can be localized. Based on this information, collision avoidance systems can be realized, by informing the vehicles operator or as break assistance system. Next to important localizations “geotags”, e.g. at crushers, the system can be used to exactly position vehicles, like LHDs to perfectly dump the moved material. Virtual fences can be realized to stop machinery if anyone enters a secured area. This enables fast operation e.g. at drill rigs, where manual work is required, when drill pipes have to be added. In room and pillar environments road crossings can be secured, by detecting exactly the own position at the crossing and observation other vehicles. Environmental Face and Rib Mapping Radar-scan Mapping is further, very advanced radar based technology to measure 2D planes or even the complete 3D environment around vehicles. As well infrastructure based usage might be considered, e.g. at crossings or crushers. Autonomous mapping radar scans algorithms are developed to reconstruct the surrounding and to detect the own driven trajectory including 3D translation, rotation. Technische Universitaet Bergakademie Freiberg Universitaetsbibliothek "Georgius Agricola" TU Bergakademie Freiberg, Geowissenschaften, Geotechnik und Bergbau 2018-03-22 doc-type:conferenceObject application/pdf http://nbn-resolving.de/urn:nbn:de:bsz:105-qucosa-231178 urn:nbn:de:bsz:105-qucosa-231178 http://www.qucosa.de/fileadmin/data/qucosa/documents/23117/10.UPNS4D%2B_RTM2017-10_1b.pdf eng
collection NDLTD
language English
format Others
sources NDLTD
topic Real-Time Mining
Konferenz
Real-Time Mining
Conference
ddc:624
Bergbau
Bergwerk
Markscheidekunde
Geoinformation
Prospektion
spellingShingle Real-Time Mining
Konferenz
Real-Time Mining
Conference
ddc:624
Bergbau
Bergwerk
Markscheidekunde
Geoinformation
Prospektion
Winkel, Reik
Rabel, Matthias
Mine Digitalization: Automation and Collision Avoidance by Radar-tag Localization and Radar-scan Mapping (UPNS4D+)
description Motivation Mine digitization is a consequent approach to establish industry 4.0 / IoT related mine operation models based on various dimensions: flexibility, coverage, real-time capability and analytics. Networking technology, wired and wireless, can be easily deployed large scale. Miniaturized sensors, thus can be placed anywhere. Laser technology has been successfully used for more than a decade in the manufacturing industry. However, due to restrictions found in challenging heavy industry environments, such as dust, fog, rain or snow, laser technology can only rarely be found in mining applications. At the same time, technology-supported geometrical environmental scanning is essential for the control of mining machines. GPS in open pit mining is the state of the art technology for machine allocation and dispatch, whereby an underground equivalent is still missing. Because of this technology gap, many machines are frequently operated beyond their original design boundaries, and not according to the production planning which may result in significant safety impacts and collisions. Recent breakthroughs in radar technology both in 2D/3D passive scanning as well as /3D Active localization is bound to trigger a revolution in mining. In close collaboration with major universities, radar technology has been developed to mature and ruggedized industrial sensors by indurad. The public funded project “UPNS4D+” which stands for “Underground 4D+ Positioning, Navigation and Mapping System“, funded by BMBF (FKZ: 033R126), focuses on fully autonomous operated vehicles, including navigation, orientation, collision avoidance by driving autonomously around obstacles whether detected with the radar-tag system or by environmental Radar-scan. Asset and Personnel Localization Radar-tags are suitable to detect any tagged object or person. Vehicle based Radar-radios are used to measure distances and angles to radar-tags, relative to the vehicle. Any other machinery, person helmets, equipment can be tagged and thus can be localized. Based on this information, collision avoidance systems can be realized, by informing the vehicles operator or as break assistance system. Next to important localizations “geotags”, e.g. at crushers, the system can be used to exactly position vehicles, like LHDs to perfectly dump the moved material. Virtual fences can be realized to stop machinery if anyone enters a secured area. This enables fast operation e.g. at drill rigs, where manual work is required, when drill pipes have to be added. In room and pillar environments road crossings can be secured, by detecting exactly the own position at the crossing and observation other vehicles. Environmental Face and Rib Mapping Radar-scan Mapping is further, very advanced radar based technology to measure 2D planes or even the complete 3D environment around vehicles. As well infrastructure based usage might be considered, e.g. at crossings or crushers. Autonomous mapping radar scans algorithms are developed to reconstruct the surrounding and to detect the own driven trajectory including 3D translation, rotation.
author2 TU Bergakademie Freiberg, Geowissenschaften, Geotechnik und Bergbau
author_facet TU Bergakademie Freiberg, Geowissenschaften, Geotechnik und Bergbau
Winkel, Reik
Rabel, Matthias
author Winkel, Reik
Rabel, Matthias
author_sort Winkel, Reik
title Mine Digitalization: Automation and Collision Avoidance by Radar-tag Localization and Radar-scan Mapping (UPNS4D+)
title_short Mine Digitalization: Automation and Collision Avoidance by Radar-tag Localization and Radar-scan Mapping (UPNS4D+)
title_full Mine Digitalization: Automation and Collision Avoidance by Radar-tag Localization and Radar-scan Mapping (UPNS4D+)
title_fullStr Mine Digitalization: Automation and Collision Avoidance by Radar-tag Localization and Radar-scan Mapping (UPNS4D+)
title_full_unstemmed Mine Digitalization: Automation and Collision Avoidance by Radar-tag Localization and Radar-scan Mapping (UPNS4D+)
title_sort mine digitalization: automation and collision avoidance by radar-tag localization and radar-scan mapping (upns4d+)
publisher Technische Universitaet Bergakademie Freiberg Universitaetsbibliothek "Georgius Agricola"
publishDate 2018
url http://nbn-resolving.de/urn:nbn:de:bsz:105-qucosa-231178
http://nbn-resolving.de/urn:nbn:de:bsz:105-qucosa-231178
http://www.qucosa.de/fileadmin/data/qucosa/documents/23117/10.UPNS4D%2B_RTM2017-10_1b.pdf
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