||Aerosol Characterization with Centrifugal Aerosol Spectrometers: Theory and Experiment.
Johnson, D. L. ;
Martonen, T. B. ;
||Health Effects Research Lab., Research Triangle Park, NC. Toxicology Branch. ;Army Medical Lab. (10th), APO New York 09180-3619.
Mathematical models ;
Experimental design ;
Particle size ;
Centrifugal classifiers ;
Equations of state ;
Occupational safety and health ;
Air pollution effects(Humans) ;
Risk assessment ;
||Some EPA libraries have a fiche copy filed under the call number shown.
||A general mathematical model describing the motion of particles in aerosol centrifuges has been developed. It has been validated by comparisons of theoretically predicted calibration sites with experimental data from tests sizing aerosols in instruments of three different spiral duct configurations. By accurately simulating factors which influence centrifuge performance, the model enhances the versatility of existing instruments and promotes CAD (computer aided design) and CAM (computer aided manufacture) of new units. The model will permit more accurate aerodynamic classifications of airborne particles. Therefore, more precise determinations of deposition sites of inhaled aerosols within the lung will be possible, since such locations are primarily functions on the dynamic characteristics of motion. U.S. EPA risk assessment protocols of pollutant aerosols will thereby be improved. (Copyright (c) 1989, American Industrial Hygiene Association.)
||Pub. in American Industrial Hygiene Association Jnl., v50 n8 p408-412 Aug 89. Prepared in cooperation with Army Medical Lab. (10th), APO New York 09180-3619.
|NTIS Title Notes
||Reprint: Aerosol Characterization with Centrifugal Aerosol Spectrometers: Theory and Experiment.
||68A; 68G; 46D; 57U
||PC A02/MF A01