Coal extraction at Premogovnik Velenje coal mine

Scanning electron microscope image of a large coal grain.

Element maps showing the distribution of mineral grain components of coal and rock dust.

Additional resources

Related websites

Related multimedia

ROCD resources

information sheet
ROCD adult leaflet on dust hazards in coal mines
- (English)
- (Polish)
‌Internet application for calculation of the distribution of dust concentration
- Introduction to dust prediction algorithm
- Application for calculation of dust levels
PDF document

Funding sources

Horizon 2020

Mining organisations and museums

Related journal papers and reports

Cowie H.A., Miller B.G., Rawbone R.G. and Soutar C. A., 2006. Dust related risks of clinically relevant lung functional deficits. Occup. Environ. Med., 63: 320–325.

Graveling R., Sanchez-Jimenez A., Lewis C. and Groat S., 2011. Protecting respiratory health: what should be the constituents of an effective RPE programme? Ann. Occup. Hyg., 1–9.

Kalukiewicz A. and Rojek P., 2011. Use of air and water aerosol in control of airborne dust concentration in mine air. KOMAG Institute of Mining Technology, Monograph 37 (accessed 8th May 2014).

Lepeule J., Laden F., Dockery D. and Schwartz J., 2012. Chronic exposure to fine particles and mortality: an extended follow-up of the Harvard Six Cities study from 1974 to 2009. Environ. Health Persp., 120: 965-70.

Moreno T., Higueras P., Jones T., McDonald I. and Gibbons W., 2005. Size fractionation in mercury-bearing airborne particles (HgPM10) at Almadén, Spain: Implications for inhalation hazards around old mines. Atmos. Env., 39: 6409–6419.

Moreno T., Oldroyd A., McDonald I. and Gibbons W., 2007. Preferential fractionation of trace metals-metalloids into PM10 resuspended from contaminated gold mine tailings at Rodalquilar, Spain. Water Air Soil Poll., 179: 93-105. NIOSH, 2011.

Coal Mine Dust Exposures and Associated Health Outcomes: A Review of Information Published Since 1995. Department of Health and Human Services, Centers for Disease Control and Prevention, National Institute for Occupational Safety and Health, Current Intelligence Bulletin 64. Persoz C., Leleu C., Achard S., Fasseu M., Menotti J., Meneceur P., Momas I., Derouin F. and Seta N., 2011.

Sequential air-liquid exposure of human respiratory cells to chemical and biological pollutants. Toxicol. Lett., 207: 53-9.

Petsonk E. L., Rose C. and Cohen R., 2013. Coal mine dust lung disease new lessons from an old exposure. Am. J. Respir. Crit. Care Med., 187: 1178–1185.

Soutar C.A., Hurley J.F., Miller B.G., Cowie H.A., and Buchanan D., 2004. Dust concentrations and respiratory risks in coalminers: key risk estimates from the British Pneumoconiosis Field Research. Occup. Environ. Med., 61: 477–481.

Tang T., Gminski R., Könczöl M., Modest C., Armbruster B. and Mersch-Sundermann V., 2011. Investigations on cytotoxic and genotoxic effects of laser printer emissions in human epithelial A549 lung cells using an air/liquid exposure system. Environ. Mol. Mutagen. 53:125-35.

Williamson B.J., Rollinson G. and Pirrie D., 2013. Automated mineralogical analysis of PM10: new parameters for assessing PM toxicity. Env. Sci. Technol., 47: 5570–5577.

Xie Y., Williams N.G., Tolic A., Chrisler W.B., Teeguarden J.G., Maddux B.L., Pounds J.G., Laskin A. and Orr G., 2011. Aerosolized ZnO nanoparticles induce toxicity in alveolar type II epithelial cells at the air-liquid interface. Toxicol. Sci., 125: 450-61.

Related past projects

This project has received funding from the Research Fund for Coal and Steel under grant agreement no. 754205.