Ventilation Optimization — Balancing the Need for More Power Against Environmental Concerns

This paper shows how the Nanisivik mine was able to improve the underground working environment, decrease operational costs, and reduce its impact on the environment through optimizing their ventilation system. Through re-organizing their ventilation system, the overall flow through the mine increas...

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Bibliographic Details
Main Authors: Hardcastle, Stephen G., Lamond, R. D., Willoughby, D. T.
Format: Text
Language:unknown
Published: Scholars' Mine 1999
Subjects:
Mine ventilation
ventilation surveys
tracer gas
ventilation network simulation
ventilation design
diesel exhaust exposure
blast clearance
GHG emissions
natural ventilation
Mining Engineering
Nanisivik
Online Access:https://scholarsmine.mst.edu/usmvs/8usmvs/8usmvs-theme17/2
https://scholarsmine.mst.edu/cgi/viewcontent.cgi?article=1093&context=usmvs
Description
Summary:This paper shows how the Nanisivik mine was able to improve the underground working environment, decrease operational costs, and reduce its impact on the environment through optimizing their ventilation system. Through re-organizing their ventilation system, the overall flow through the mine increased by at least 20%, and local flows increased by over 100%. This change also resulted in a 45% reduction of fan motor power. And as a consequence of reduced power demands the mine has decreased its Green-house gas (GHG) emissions. Currently, ventilation is typically responsible for 40% of a Canadian mine's underground electrical consumption. This could dramatically change as the relationship between air supplied by fans and the power consumed is a cubic. Nanisivik is just one example of how the Canadian mining industry is striving to remain competitive under the general pressures to supply more or better quality ventilation for the workforce but on the other hand reduce power consumption.

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