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Penetration of ambient fine particles into the indoor environment

Mosley, R. B., Greenwell, D. J., Sparks, L. E., Guo, Z., Tucker, W. G., Fortmann, R. and Whitfield, C.
2001
Aerosol Science and Technology, 34(1): 127-136

Mosley, R. B., Greenwell, D. J., Sparks, L. E., Guo, Z., Tucker, W. G., Fortmann, R. and Whitfield, C., (2001), "Penetration of ambient fine particles into the indoor environment", Aerosol Science and Technology, 34(1): 127-136.
Abstract:
Several recent studies have indicated significant health risks associated with exposure to fine particles as measured outdoors. However, much of the exposure is believed to have occurred indoors. Consequently, there is considerable interest in the relationship between indoor and outdoor line particles. This paper describes some results from a study in which the processes of particle removal from infiltrating air by building envelopes are simulated in a chamber. The chamber consists of two compartments, each having a volume of 19 m3. Particles with aerodynamic diameters in the range of 0.05 to 5 m are generated in one compartment and then transported through simulated leakage paths to the other compartment under the action of applied pressure differentials. The simulated leakage paths described in this paper consist of horizontal slits (0.508 mm high, 102 mm deep, and 433 mm wide) between aluminum plates. The penetration factor for each size particle is determined by simultaneously measuring the concentrations in the two compartments as a function of time. The penetration factor is obtained through a mathematical solution of the mass balance equations. The measured values of penetration are compared to predictions of a mathematical model describing deposition by the mechanisms of settling and diffusion. At applied pressures of 2 Pa, only 2% of 2 m particles and 0.1% of 5 m particles pass through the 0.508 mm high slits. At a pressure of 5 Pa, 40% of 2 m particles and <1% of 5 m particles pass through the slits. At 10 Pa, 85% of 2 m particles and <1% of 5 m particles pass through the slits. At 20 Pa, 90% of 2 m particles and 9% of 5 m particles pass through the slits. Measured deposition rate constants for particles spanning the range 0.015 to 5 m in diameter are shown.
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Author Information and Other Publications Notes
Mosley, R. B.
National Risk Management Research Laboratory, United States Environmental Protection Agency, Research Triangle Park, North Carolina
  1. Chamber simulation of fine particle penetration into houses
  2. Penetration of particles into buildings and associated physical factors. part I: model development and computer simulations  
Greenwell, D. J.
     
Sparks, L. E.
National Risk Management Research Laboratory, United States Environmental Protection Agency, Research Triangle Park, North Carolina
  1. Gas-phase mass transfer model for predicting volatile organic compound (VOC) emission rates from indoor pollutant sources
  2. Penetration of particles into buildings and associated physical factors. part I: model development and computer simulations  
Guo, Z.
  1. Design and characterization of a small chamber for chemical and biological evaluation of sources of indoor air contamination  
Tucker, W. G.
     
Fortmann, R.
     
Whitfield, C.
     


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