Record Display for the EPA National Library Catalog

RECORD NUMBER: 4 OF 14

OLS Field Name OLS Field Data
Main Title Dense Gas Removal from a Valley by Crosswinds.
Author Briggs, G. A. ; Thompson, R. S. ; Snyder, W. H. ;
CORP Author Environmental Protection Agency, Research Triangle Park, NC. Atmospheric Research and Exposure Assessment Lab.
Publisher c1990
Year Published 1990
Report Number EPA/600/J-90/305;
Stock Number PB91-146597
Additional Subjects Dissipation ; Valleys ; Wind effects ; Gases ; Hazardous materials ; Wind tunnels ; Simulation ; Topographic features ; Air pollution ; Carbon dioxide ; Sulfur fluorides ; Reynolds numbers ; Froude number ; Reprints ;
Holdings
Library Call Number Additional Info Location Last
Modified
Checkout
Status
NTIS  PB91-146597 Most EPA libraries have a fiche copy filed under the call number shown. Check with individual libraries about paper copy. NTIS 06/13/1991
Collation 40p
Abstract
Wind tunnel experiments were made to determine how rapidly dense gas trapped in a topographic depression could be removed by an entraining crosswind. The two-dimensional outflow volume flux, vo, was assumed equal to the inflow rate during 92 steady-state experiments with CO2 continuously supplied into the bottom of two-dimensional, V-shaped valleys. As predicted by theory, at large Reynolds numbers it was found that vo is approximately equal to Us(3)/gi, where Us is the speed just above the dense gas pool and gi' is gravity times the relative density difference. The width of the pool, w, does not affect vo when the primary Froude number < 1, except at low Reynolds numbers; in this case the data suggest vo is approximately equal to (Us wK)1/2 as an asymptote, where k is the molecular diffusivity. A universal relationship is suggested for vo bridging these two asymptotes. Transient experiments were conducted by filling a valley with dense gas, turning it off, then quickly removing a sliding cover; vo was measured as a function of time with an array of samplers downwind. These experiments essentially confirmed predictions based on the steady-state results, even when SF6 was substituted for CO2.