1 / 23

Managing Heat Exposure in Canada’s Underground Mines

MMSL Technical Workshop – March 25 – 26, 2010. Managing Heat Exposure in Canada’s Underground Mines. Steve Hardcastle RC 140 – Underground Mine Environment. Presentation Outline. Acknowledgements Introduction Impact Research Objectives Research Methodology Results

vilina
Download Presentation

Managing Heat Exposure in Canada’s Underground Mines

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. MMSL Technical Workshop – March 25 – 26, 2010 Managing Heat Exposure in Canada’s Underground Mines Steve Hardcastle RC 140 – Underground Mine Environment

  2. Presentation Outline • Acknowledgements • Introduction • Impact • Research Objectives • Research Methodology • Results • Interpretation and Discussion • Other Work • Conclusion/Recommendations • Next Steps

  3. Acknowledgements • Deep Mining Research Consortium (Agnico-Eagle, Barrick Gold, Xstrata, Goldcorp, Vale Inco, Rio Tinto, Industry Canada, Ontario’s Northern Development and Mines, City of Greater Sudbury) • University of Ottawa (Drs Glen Kenny & Frank Reardon, Research Associates and test subjects) • Agnico Eagle, Vale Inco, Xstrata Nickel, FNX Mining (Provision of test sites and subjects) • Mines and Aggregates Safety and Health Association’s Ontario Mine Rescue Program • WSIB, NSERC, University of Ottawa Research Chair, Canada Foundation for Innovation (Parallel funding) • Kevin Butler, Charles Kocsis, Gary Li (MMSL Staff)

  4. Introduction • The research is comprised of a suite of projects performed by the University of Ottawa and CANMET-MMSL in co-operation with the mining industry and safety agencies. • The issue, with a changing surface climate, greater depth and continued mechanization using larger equipment, Canadian underground mine workers have an increasing risk to be exposed to heat stress • This is not only a health and safety issue for the worker but also a productivity and cost issue for the mining company. • Reducing exposure time limits productivity and changing the thermal environment is expensive

  5. Impact Program Activity Architecture (PAA) 1.1.1 Innov. & Prod. – 20% 2.2.1 Strong Env. Perf. – 30% 3.1.1 Mining Safety – 50% • Mining safety may seem to be the driving factor but how heat is managed affects productivity and a mine’s environmental impact • To combat heat you either need more air or chilled air both can be multi-$M investments and consume significant power that produce GHGs. • Reducing productive face time affects profitability. Improved guidelines and methods to determine ventilation volumes and refrigeration can increase productivity and help competitiveness.

  6. Research Objectives • Due to the cost and safety issues, industry, workers and regulatory agencies need a better understanding of what are the causal factors contributing to heat stress in mines and how they can be managed • Analyze mining activity and conditions • Simulate under controlled laboratory conditions (current & future – adverse) • Explore clothing, age, fitness, work practices • Evaluate current management practices and exposure monitoring • Develop more appropriate guidelines and mitigating strategies

  7. Research Methodology Four aspects of the physiological research • Laboratory Task Simulation • Mine Rescue Assessment • Clothing • Work : Recovery Exposure Management Protocols

  8. Research - Task Analysis • Equipment – Physiological Testing Skin / Core Temperatures O2 / Energy Consumption Heat Production/ Storage

  9. Research - Task Analysis • Experimental procedures - Example • The Movements (Tasks)T#1: Sitting T#2: Treadmill (legs)T#3: Pulleys (arms) T#4= T#2 + T#3 • Schedule - Occupation 1 (Bolting) T#2 (4 min), T#1 (3 min), T#4 (9 min), T#2 (1 min), T#4 (48 min), T#1 (1 min), T#4 (2 min), T#1 (16 min), T#4 (29 min), T#2 (7 min). • Similar schedules for 3 other occupational groups • Simulations under “normal” and “adverse” environmental conditions Miner Work Simulation

  10. 30ºC 60RH 35ºC 60RH 39ºC 60RH 35ºC 40RH 35ºC 80RH Results – Adverse Conditions Subjects unable to complete test Environment 38.5 CoreLimit 38.0 37.5 Rectal Temperature (ºC) Work 1: 386 W 2: 360 W 37.0 3: 345 W 4: 227 W 1 2 3 6 4 5 5: 365 W 36.5 6: 285 W 0 20 40 60 80 100 120 Time (min)

  11. Research – Upper Limit • Extreme Task – Mine Rescue 10 Subjects Average SD Age (yrs) 25 - 62 47 9 Height (m) 1.78 0.07 Weight, Semi-nude (kg) 87.4 12.1 Body Fat (%) 19.7 3.9 Equipment (kg) 21.9 1.7

  12. Research - Upper Work Limit • Rescue Team 4 + 1 Simulated ExerciseRepeated 5 times • Loads: 25-155 kg • Incline: 0-20% • Distance: 0-250 m • Temperature:< 20C • Work: 400-750W • 5 Ramp & 2 Level Elements • Duration 65 mins

  13. 38.2 680 ) ºC ( 38.0 600 37.8 520 Average Core Temperature 37.6 440 37.4 360 ) 2 37.2 280 Energy (W/m 37.0 200 36.8 120 0 10 20 30 40 50 60 70 Elapsed Time (min) Results – Rescuers already at risk • 5 Tests x 2 Subjects • 3 subjects >38C within 20 – 50 min. • Environment very cool compared to a deep mine • Clothing limits evaporation of sweat / promotes heat storage Continuous increase No recovery at lighter work rates

  14. Research – Clothing Properties • Evaluating the human/clothing system WickingUndergarment CoverallsFull PPE Work PantWicking T-Shirt

  15. Research – Clothing Phase 1 Initial Tests performed under abstract conditions to isolate benefits of specific clothing ensembles • Test in hot and dry to maximize evaporation potential • Limit air velocity to avoid discomfort during the recovery period. • Choose “heavy” work rate: cycling @ 400 W, to generate a high heat load/greatest cooling potential across clothing • 5 clothing ensembles including semi-nude control • 8 subjects tested under each condition • 60-minutes of work, 60-minutes of recovery

  16. Control - Shorts Mine gear only Undergarment only 1.0 Mine gear + undergarment 37.66ºC 0.8 0.6 Esophageal Temperature (ºC) 0.4 0.2 37.25ºC Exercise Recovery 0.0 0 15 30 45 60 75 90 105 120 Time (min) -0.2 Results - Clothing • Change in core temperature • Less heat loss with coveralls causes core temperature to continually rise • Sportswear similar to being naked • Coveralls store more heat when resting • Note length of recovery decay and residual heat

  17. Research – Heat Storage/Recovery Other research has shown heat to be cumulatively stored with each repeated work session. Tests performed in University of Ottawa’s calorimeter • Same level of exercise (360W) used throughout • 4 trials of 8 subjects, random order • The environmental temperature is increased through Trials 1 to 4, from 28 to 31.5C wet-bulb • Work duration and recovery adjusted as temperature increased, from 100% work, through 75:25, 50:50 and 25:75 work/recovery regimes • Subjects wore work-pants, wicking t-shirt and full mine PPE

  18. Results – Protocol Increasingly over-protective • 120 mins of continuous work completed without exceeding 38C • Final core temperature decrease through trials • Recovery period more than compensates for the higher environmental temperature Trial 1 Trial 2 Trial 3 Trial 4 38.2 38.0 37.8 37.6 Rectal Temperature (°C) 37.4 37.2 37.0 0 15 30 45 60 75 90 105 120 Time (min)

  19. Interpretation and Discussion • Results shown are snap-shots • The body of data needs to be assessed en masse • Other issues/avenues of research • Age/Fitness • Wind speed • Hydration • Increased air density at depth • Optimum recovery time • Improved work:rest protocols

  20. Other Work – CANMET Roles • CANMET-MMSL are not only responsible for managing & advising in the heat stress research. • It has had specific responsibilities to evaluate the suitability of instrumentsused to assess the thermal environment – these are what the industry will use to determine acceptability • It has also helped identify why it can become hot underground and how it could be addressed – it may be a very simple ventilation solution • It has also been tasked with the University of Ottawa to produce a non-medical handbook

  21. Conclusions/Recommendations • This research has benefited from the use of the University of Ottawa’s calorimeter. • Nobody else has, or has had, a similar Gold Standard facility to truly investigate heat stress. • This research thrust has generated a significant amount of useful data during the last 5 years. • The industry’s present interest is now to communicate this science and to develop better heat management strategies. • This work could also help modify the current regulations to something more scientifically based.

  22. Next Steps • Complete current testing schedule • Communicate the science to the client • CIM presentations, Ventilation Symposium Workshop • Continue with Peer reviewed publications, these are needed to facilitate any change in regulations or to adopt something different • Support the harmonization of regulations and delivering a common scientifically founded message through the available guidelines • Seeking funding/support for the additional issues

  23. Questions?

More Related