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Distribution of particle and gas concentrations in Swine gestation confined animal feeding operations.
Peters TM; Anthony TR; Taylor C; Altmaier R; Anderson K; O'Shaughnessy PT
Ann Occup Hyg 2012 Nov; 56(9):1080-1090
OBJECTIVES: Dust mass concentrations, temperatures, and carbon dioxide concentrations were mapped in a modern, 1048-pen swine gestation barn in winter, spring, and summer. METHODS: In each season, two technicians measured respirable mass concentrations with an aerosol photometer and temperatures and carbon dioxide concentrations with an indoor air quality monitor at 60 positions in the barn. Stationary photometers were also deployed to measure mass concentrations during mapping at five fixed locations. RESULTS: In winter when building ventilation rates were low (center-barn mean air velocity=0.34 m s(-1), 68 fpm) to conserve heat within the barn, mass and carbon dioxide concentrations were highest (mass geometric mean, GM=0.50 mg m(-3); CO2 GM=2060 ppm) and fairly uniform over space (mass geometric standard deviation, GSD=1.48; CO2 GSD=1.24). Concentrations were lowest in summer (mass GM=0.13 mg m(-3); CO2 GM=610 ppm) when ventilation rates were high (center-barn mean air velocity=0.99 m s(-1), 196 fpm) to provide cooling. Spatial gradients were greatest in spring (mass GSD=2.11; CO2 GSD=1.50) with low concentrations observed near the building intake, increasing to higher concentrations at the building exhaust. CONCLUSIONS: Mass concentrations obtained in mapping were generally consistent with those obtained from stationary monitors. A moderately strong linear relationship (R2=0.60) was observed between the log of photometer-measured mass concentration and the log of carbon dioxide concentration, suggesting that carbon dioxide may be an inexpensive alternative to assessing air quality in a swine barn. These results indicate that ventilation can effectively reduce contaminant levels in addition to controlling temperature.
Dusts; Dust particles; Agriculture; Farmers; Livestock; Livestock industry; Respiratory irritants; Respiration; Air quality; Ventilation; Monitors; Animals; Analytical processes; Airborne dusts; Airborne particles; Air contamination; Pollution; Pollutants; Environmental pollution; Environmental exposure; Author Keywords: aerosol mapping; agricultural exposures; particulate matter; swine barn; ventilation
Thomas M. Peters, The University of Iowa, Occupational and Environmental Health, Iowa City, IA, USA
Cooperative Agreement; Grant
Cooperative-Agreement-Number-U50-OH-007548; Cooperative-Agreement-Number-U54-OH-007548; Grant-Number-T42-OH-008491
Issue of Publication
Agriculture, Forestry and Fishing
Annals of Occupational Hygiene
University of Iowa, Iowa City
Page last reviewed: July 9, 2021
Content source: National Institute for Occupational Safety and Health Education and Information Division