Summary
This paper describes automation of the digging cycle of a mining rope shovel which considers autonomous dipper (bucket) filling and determining methods to detect when to disengage the dipper from the bank. Novel techniques to overcome dipper stall and the online estimation of dipper “fullness” are described with in-field experimental results of laser DTM generation, machine automation and digging using a 1/7th scale model rope shovel presented.
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References
Dragline Swing Assist: ACARP C9028-final report. Technical report, ACARP, 2003.
L. Bernold. Motion and path control for robotic excavation. ASCE J. Aerospace Engineering, 6(1):1–19, January 1993.
P. Corke and M. Dunbabin. ACARP Project C12030 Rope shovel automation. Technical report, ACARP, 2004.
P. Corke, P. Sikka, J. Roberts, and E. Duff. DDX: A distributed software archetecture for robotic systems. In Australasian Conference on Robotics & Automation, Canberra, December 2004.
A. Hemami. Modelling, analysis and preliminary studies for automatic scooping. Advanced Robotics, 8(5):511–529, 1994.
A. Hemami and S. Goulet. Resistance of particulate media to excavation: Application to bucket loading. Int. J. Surface Mining, Reclamation and Environment, 8:125–129, 1994.
J. Roberts, G. Winstanley, and P. Corke. Three-dimensional imaging for a very large excavator. International Journal of Robotics Research, 22(7–8):467–477, 2003.
P.S. Rowe. Learning system and method for optimizing control of autonomous earthmoving machinery. US Patent 6,076,030, June 2000.
X. Shi, F.-Y. Wang, and P.J.A. Lever. Experimental results of robotic excavation using fuzzy behavior control. Control Eng. Practice, 4(2):145–152, 1996.
S. Singh. Learning to predict resistive forces during robotic excavation. In International Conference on Robotics & Automation, pages 2102–2107, Nagoya, May 1995.
S. Singh. The state of the art in autonomous earthmoving, 2002. In Workshop on Advanced Geomechatronics, Sendai, Japan, 2002.
S. Singh and H. Cannon. Method and apparatus for determining an excavation strategy. US Patent 6,108,949, August 2000.
Carnegie-Mellon University. System for autonomous excavation and truck loading. UK Patent GB 2,342,640, April 2000.
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© 2006 Springer-Verlag Berlin Heidelberg
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Dunbabin, M., Corke, P. (2006). Autonomous Excavation Using a Rope Shovel. In: Corke, P., Sukkariah, S. (eds) Field and Service Robotics. Springer Tracts in Advanced Robotics, vol 25. Springer, Berlin, Heidelberg . https://doi.org/10.1007/978-3-540-33453-8_46
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DOI: https://doi.org/10.1007/978-3-540-33453-8_46
Publisher Name: Springer, Berlin, Heidelberg
Print ISBN: 978-3-540-33452-1
Online ISBN: 978-3-540-33453-8
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