Effective utilization of man shift through sustainable workload testing for underground mining machine operators. An ergonomic based man-machine interface approach

Dey, Netai Chandra; Dey, Shibaji

doi:10.2478/ntpe-2019-0042

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Tytuł artykułu

Effective utilization of man shift through sustainable workload testing for underground mining machine operators. An ergonomic based man-machine interface approach

Autorzy

Dey Netai Chandra , Dey Shibaji

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DOI

10.2478/ntpe-2019-0042

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Języki publikacji

Abstrakty

Insight of man-machine interfaces during mining machine operations, better co-ordinance with human efficiencies and suitable workload selection in underground mining machine operation are the main viewpoints of the study. Total 12 side discharge loader (SDL) and load haul dumper (LHD) operators [N = 12] have been taken as participants of the study. The methodology is divided into two parts first part is devoted to measuring and analyzing workload response of machine operation with polar heart rate monitor. Machine operator’s heart rate ratio (HR ratio) for the whole shift is recorded and metabolic rate (MR) has been analyzed. Additionally, fatigue sustainability (FS) and degradation of muscle force (MF) are recorded for each work cycles up to exposure time period (ETP) of 360 minutes. In the second part of the methodology, based on the HR ratio recorded during the mining operation, a workload simulation study is undertaken on a treadmill at the surface following BRUCE protocol. At treadmill, based on HR ratio, workload achieved from mines along with three different workloads i.e. low, moderate and high has been tested. Differences in FS and degradation rate of MF after each workload experiment have been recorded. A result from the underground operational study shows that there is about 43.2% and 32.4% of decreasing MF for SDL and LHD operators after end of spells at mines. Additionally, a negative correlation (r = -0.99) is found between ETP and MF. The workload simulation study shows that there are significant differences between FS (p < 0.05) and MF (p < 0.05) data of mining and treadmill experiment with the same workload. In comparison to an underground operation, FS rate of low, moderate and high workload is recorded 60%, 35%, and 15% higher respectively than of mine workload. Higher FS rate may achieve due to availability of good environment. Among the tested workload only low kind of workload is found suitable for mining machinery job as degradation of MF is found significantly (p < 0.05) low and FS is found significantly (p < 0.01) high in this kind of workload. Therefore, it can be concluded that in mining machinery operation better to adopt low workload for effective utilization of man shift (EUMS) as it gives comparatively low MF degradation and better FS during continuous work.

Słowa kluczowe

fatigue sustainability FS muscle force MF heart rate ratio HR ratio exposure time period ETP effective utilization of man shift EUMS workload simulation

siła mięśni obciążenie pracą okres ekspozycji degradacja zmęczeniowa tętno środowiskowe warunki pracy

Wydawca

STE GROUP
De Gruyter

Czasopismo

New Trends in Production Engineering

Rocznik

2019

Tom

Vol. 2, Iss. 1

Strony

394--403

Opis fizyczny

Bibliogr. 23 poz., rys., tab.

Twórcy

autor

Dey Netai Chandra

Indian Institute of Engineering Science and Technology Shibpur, India

autor

Dey Shibaji

Indian Institute of Engineering Science and Technology Shibpur, India

Bibliografia

1. Akinpelu D. (2017,August 27)., “Treadmill Stress Testing Technique. Retrieved from: https://emedicine.medscape.com/article/1827089-technique.
2. Åstrand. P. O., Rodhal K., Dahl H.A., Stromme S.B. (2003) Text Book of Work Physiology. 4th ed. Canada: Human Kinetics.
3. Biswas R., Samanta A.,Saha P. (2011) "Cardiac strain of confectionery worker in relation to heat exposure during regular work shift." Indian journal of occupational and environmental medicine 15(3), pp. 120-126.
4. Bruce, R. A. (1972) "Exercise testing and training of apparently healthy individuals: a handbook for physicians." New York, USA: American Heart Association.
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6. Dey N.C., Dey S C., Sharma G D.(2017) "Importance of ergonomic application for the improvement of coal productivity in mines." Proceedings of the 17th Coal Operators’ Conference.2017: pp. 306-313.
7. Dey N C., Nath S., Sharma G D., Dey S C. (2015a). "An Inventory Approach to Humanizing Work and Work Environment in Indian Underground Coal Mines". Research Updates in Medical Sciences (Rumes), 3(3), pp. 10-18.
8. Dey N C., Nath S., Sharma G D., Mallick A. (2014) "Environmental impact on physiological responses of underground coal miners in the eastern part of india." Journal of Human Ergology 43(2), pp. 69-68.
9. Dey N C., Samanta A., Saha R.(2006) "A study of the workload of underground trammers in the Ranigang coalfield area of West Bengal, India.” International Journal of Occupational Safety and Ergonomics 12 (4), pp. 399-407.
10. Dey N C., Sharma G D.,Dey S. (2015b)“An ergonomic study of health of drillers working in an underground coal mine with adverse environmental conditions” MGMI Trans. 111: pp. 58-65.
11. Dey, S C., Dey N C., Sharma G D.(2018). "Occupational Malfunctioning and Fatigue Related Work Stress Disorders (FRWSDs): An Emerging Issue in Indian Underground Mine (UGM) Operations." Journal of the Institution of Engineers (India): Series D. 99(1), pp. 103-108.
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17. Hull B.P., Leigh J., Driscoll T.R. & Mandryk J. (1996). Factors associated with occupational injury severity in the New South Wales underground coal mining industry. Safety Science, 21(3), 191-204.
18. Mining in India. (2018, March 5). Retrieved from: https://en.m.wikipedia.org/wiki/mining_ in India#cite_note-cci-1
19. Ratner, B. (2009). The correlation coefficient: Its values range between+ 1/− 1, or do they? Journal of targeting, measurement and analysis for marketing, 17(2), pp. 139-142.
20. Sharma G.D., Dey S., Dey N.C.(2016) "Rationalising postural demand of side discharge loading machine operators with respect to musculoskeletal pain and discomfort in underground coal mines in India." International Journal of Human Factors and Ergonomics 4(1), pp. 60-72.
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Uwagi

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).

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Bibliografia

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