This
study presents the effect of excavator model, loading operation location, shift
availability and truck-shovel combination on loading cycle time and productivity of an open-pit mine. The loading cycle
time was used to assess the material loading system performance which is one of
the key components of the total cycle time for material transportation in an
open-pit mine. Loading is among the components of cycle time during which
material is being handled. The data analyzed?was?collected from a
computerized dispatch system at GGM from which 62,000 loading dispatches per
month involving several shifts, 14 excavators and 49 trucks were loaded. About
4465 dispatches per excavator and 1276 dispatches per truck were assessed using
loading cycle time data for each dispatch for a period of four months (between
August and December). Under fixed tonnage loaded and waste type (33 t of
non-acid forming waste rock),?it was observed that loading cycle time depends on excavator model,
location and truck being loaded. Average cycle times, PDFS?and CDFS of
loading cycle time series were used to identify differences in performance under
different situations. It was concluded that shift availability for excavators,
loading location, excavator model and truck-shovel combinations strongly affect
the productivity during loading process in an open-pit mine.
References
[1]
Hendricks, C., Peck, J. and Scoble, M. (1991) Machine Performance Monitoring in Surface Mines. Mining Engineering, 44, 243-250.
[2]
Osanloo, M. and Hekmat, A. (2005) Prediction of Shovel Productivity in the Gol-e-Gohar Iron Mine. Journal of Mining Science, 41, 177-184.
https://doi.org/10.1007/s10913-005-0081-5
[3]
Ercelebi, S.G. and Bascetin, A. (2009) Optimization of Shovel-Truck System for Surface Mining. Journal of the Southern African Institute of Mining and Metallurgy, 109, 433-439.
[4]
Fujita, K., Yasuda, T. and Imaie, K. (2011) Ultra Large Hydraulic Excavators and Dump Trucks for Large Open-Pit Mines. Hitachi Review, 60, 267-271.
[5]
Nel, S., Kizil, M.S. and Knights, P. (2011) Improving Truck-Shovel Matching. 35th APCOM Symposium, Wollongong, NSW, 381-391.
[6]
Kirmanli, C. and Erceleni, S.G. (2009) An Expert System for Hydraulic Excavator and Truck Selection in Surface Mining. The Journal of the Southern African Institute of Mining and Metallurgy, 109, 727-739.
[7]
Vemba, M.M.D.S. (2004) Loading and Transport System at SMC-Optimization. The Journal of the South African Institute of Mining and Metallurgy, 104, 139-147.
[8]
Choudhary, R.P. (2015) Optimization of Load-Haul-Dump Mining System by OEE and Match Factor for Surface Mining. International Journal of Applied Engineering and Technology, 5, 96-102.
[9]
JideMuili A., Adiodun, I.L. and Adeyemi, E.A. (2013) Optimization of the Overall Equipment Efficiency (OEE) of Loaders and Rigid Frame Trucks in NAMDEB Southern Coastal Mine Stripping Fleet, Namibia. Earth Science, 2, 158-166.
[10]
Singh, S.P. and Narendrula, R. (2006) Factors Affecting the Productivity of Loaders in Surface Mines. International Journal of Surface Mining, Reclamation and Environment, 20, 20-32. https://doi.org/10.1080/13895260500261574
[11]
Louit, D.M. and Knights, P.F. (2001) Simulation of Initiatives to Improve Mine Maintenance. Mining Technology, 110, 47-58.
https://doi.org/10.1179/mnt.2001.110.1.47
[12]
Meech, J. and Parreira, J. (2011) An Interactive Simulation Model of Human Drivers to Study Autonomous Haulage Trucks. Procedia Computer Science, 6, 118-123.
[13]
Olaiya, F. and Adeyemo, A.B. (2012) Application of Data Mining Techniques in Weather Prediction and Climate Change Studies. International Journal of Information Engineering and Electronic Business, 4, 51-59.
https://doi.org/10.5815/ijieeb.2012.01.07
[14]
Thompson, R.J. and Visser, A.T. (2003) Mine Haul Road Maintenance Management Systems. Journal of the South African Institute of Mining and Metallurgy, 103, 303-312.
[15]
Nieto, A., Sun, E. and Li, Z. (2010) Real-time Assisted Driving in Open-Pit Mining Operations Using Google Earth. Mining Engineering, 62, 21-26.
