Record Display for the EPA National Library Catalog

RECORD NUMBER: 6 OF 23

OLS Field Name OLS Field Data
Main Title Effects of temperature and pressure on particle collection mechanisms : [microfiche] : theoretical review /
Author Parker, Richard. ; Jain, R. ; Le, T. ; Calvert, S.
CORP Author Air Pollution Technology, Inc., San Diego, CA.;Industrial Environmental Research Lab., Research Triangle Park, NC.
Publisher Environmental Protection Agency, Office of Research and Development, Industrial Environmental Research Laboratory ; For sale by the National Technical Information Service,
Year Published 1984
Report Number EPA-68-02-2137; EPA-600/7-84-030
Stock Number PB84-168921
Additional Subjects Air pollution control equipment ; High temperature tests ; High pressure tests ; Particles ; Cyclone separators ; Performance evaluation ; Sampling ; Brownian movement ; Diffusion ; Mathematical models ; Design criteria ; Electrical properties ; Numerical solution
Holdings
Library Call Number Additional Info Location Last
Modified
Checkout
Status
NTIS  PB84-168921 Most EPA libraries have a fiche copy filed under the call number shown. Check with individual libraries about paper copy. NTIS 01/01/1988
Collation 169 pages : illustrations ; 28 cm.
Abstract
The report gives results of a theoretical and experimental investigation of the effects of high temperatures and high pressures (HTPs) on fundamental particle collection mechanisms. It gives experimental results of inertial impaction, cyclone separation, Brownian diffusion, and electrical migration tests at HTPs. The inertial impaction tests showed that existing impaction models are adequate for HTP predictions. Practical problems (e.g., materials, seals, and particle adhesion) pose more difficulties than any fundamental variations from impaction theory. The cyclone tests showed that cyclone efficiency decreases at high temperature and increases at high pressure for a constant inlet velocity. Available theoretical models could not predict the observed effects of HTP on collection efficiency. An empirical correlation for predicting the cyclone cut diameter was derived. Existing pressure-drop models predict the effects of HTP fairly well. The Brownian diffusion tests showed no detectable effects of HTP. This result is consistent with predictions for the particle size used in the tests (dp > 0.5 micrometer). No useful high temperature data were obtained with the electrical migration apparatus.
Notes
Includes bibliographical references. Issued March 1984. Microfiche,