An experimental study is presented of the ability of fine meshes to remove fog drops from an air flow. Specifically, the collection efficiency (CE) was measured for fog drops passing through mesh fabrics. Meshes composed of cotton, nylon, and Teflon were investigated, and the effect of the material as well as mesh porosity was determined. Collection efficiencies ranging from 5% to 50% were obtained. The ultimate goal of this work is to employ such meshes in a parachute configuration above power plant cooling towers, so that condensed fog may be collected and returned to the cooling loop. It is shown that the drop diameters and velocities investigated here are similar to those observed above cooling towers.
Issue Section:
Technical Brief
References
1.
Kenny
, J. F.
, Barber
, N. L.
, Hutson
, S. S.
, Linsey
, K. S.
, Lovelace
, J. K.
, and Maupin
, M. A.
, 2009
, “Estimated Use of Water in the United States in 2005
,” USGS
, Reston, VA, Technical Report No. 1344.2.
Hensley
, J. C.
, ed., 2009
, Cooling Tower Fundamentals
, 2nd ed., SPX Cooling Technologies
, Overland Park, KS
.3.
Solley
, W. B.
, Pierce
, R. R.
, and Perlman
, H. A.
, 1998
, “Estimated Use of Water in the United States in 1995
,” USGS
, Reston, VA, Technical Report No. 1200.4.
Foster
, P. M.
, Williams
, M. I.
, and Winter
, R. J.
, 1974
, “Droplet Behavior and Collection by Counterflow Cooling Tower Eliminators
,” Atmos. Environ.
, 8
(4
), pp. 349
–360
.5.
Chan
, J.
, and Golay
, M. W.
, 1977
, “Comparative Performance Evaluation of Current Design Evaporative Cooling Tower Drift Eliminators
,” Atmos. Environ.
, 11
(8
), pp. 775
–781
.6.
Becker
, B. R.
, and Burdick
, L. F.
, 1992
, “Effect of Drift Eliminator Design on Cooling Tower Performance
,” ASME J. Eng. Gas Turbines Power
, 114
(4
), pp. 632
–642
.7.
Cho
, R.
, 2011
, “The Fog Collectors: Harvesting Water From Thin Air
,” Water Matters
, The Earth Institute
, Columbia University, New York
.8.
Fessehaye
, M.
, Abdul-Waham
, S. A.
, Savage
, M. J.
, Kohler
, T.
, Gherezghiher
, T.
, and Hurni
, H.
, 2014
, “Fog-Water Collection for Community Use
,” Renewable Sustainable Energy Rev.
, 29
, pp. 52
–62
.9.
Schemenauer
, R. S.
, and Joe
, P.
, 1989
, “The Collection Efficiency of a Massive Fog Collector
,” Atmos. Res.
, 24
(1–4
), pp. 53
–69
.10.
Schemenauer
, R. S.
, and Cereceda
, P.
, 1994
, “Fog Collection's Role in Water Planning for Developing Countries
,” Nat. Resour. Forum
, 18
(2
), pp. 91
–100
.11.
Ran
, W.
, Saylor
, J. R.
, and Holt
, R. G.
, 2014
, “Improved Particle Scavenging by a Combination of Ultrasonics and Water Sprays
,” J. Aerosol Sci.
, 67
, pp. 104
–118
.12.
Elonka
, S.
, 1963
, “Cooling Towers: A Special Report
,” Power
.13.
Rothman
, T.
, and Ledbetter
, J. O.
, 1975
, “Droplet Size of Cooling Tower Fog
,” Environ. Lett.
, 10
(3
), pp. 191
–203
.14.
Hanna
, S. R.
, 1975
, “Meteorological Effects of the Mechanical-Draft Cooling Towers of the Oak Ridge Gaseous Diffusion Plant
,” Environmental Research Laboratories 1974 Annual Report
, R. P.
Hosker
and R. A.
Green
, eds., National Oceanic and Atmospheric Administration, Oak Ridge, TN, pp. 55
–70
.15.
Hall
, W. A.
, 1962
, “Elimination of Cooling Tower Fog From a Highway
,” J. Air Pollut. Control Assoc.
, 12
(8
), pp. 379
–383
.16.
Chen
, N.
, and Hanna
, S.
, 1967
, “Drift Modeling and Monitoring Comparisons
,” Atmos. Environ.
, 12
(8
), pp. 1725
–1734
.17.
Roffman
, A.
, and Van Vleck
, L.
, 1974
, “The State-of-the-Art of Measuring and Predicting Cooling Tower Drift and Its Deposition
,” J. Air Pollut. Control Assoc.
, 24
(9
), pp. 855
–859
.18.
Ruiz
, J.
, Kaiser
, A. S.
, Ballesta
, M.
, Gil
, A.
, and Lucas
, M.
, 2013
, “Experimental Measurement of Cooling Tower Emissions Using Image Processing of Sensitive Papers
,” Atmos. Environ.
, 69
, pp. 170
–181
.19.
1977
, “Chalk Point Surface Weather and Ambient Atmospheric Profile Data: Second Intensive Test Period, June 14–24, 1976
,” Chalk Point Cooling Tower Project Data Report, Applied Physics Laboratory and Maryland Power Plant Siting Program, Johns Hopkins University, Baltimore, MD.20.
Lucas
, M.
, Martinez
, P. J.
, Ruiz
, J.
, Kaiser
, A. S.
, and Viedma
, A.
, 2010
, “On the Influence of Psychrometric Ambient Conditions on Cooling Tower Drift Deposition
,” Int. J. Heat Mass Transfer
, 53
(4
), pp. 594
–604
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