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WRRCTR No.144 Water Quality of Airport Storm Runoff

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Title: WRRCTR No.144 Water Quality of Airport Storm Runoff
Authors: Christakos-Comack, Elizabeth
Dugan, Gordon L.
Keywords: storm runoff
water supply
water quality standards
water sampling
pollutant identification
show 4 moreheavy metals
Honolulu International Airport
nonpoint pollution

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LC Subject Headings: Nonpoint source pollution -- Hawaii -- Oahu.
Urban runoff -- Hawaii -- Oahu.
Water -- Pollution -- Hawaii -- Oahu.
Water quality -- Measurement -- Hawaii -- Oahu.
Issue Date: Jul 1982
Publisher: Water Resources Research Center, University of Hawaii at Manoa
Citation: Christakos-Comack E, Dugan GL. 1982. Water quality of airport storm runoff. Honolulu (HI): Water Resources Research Center, University of Hawaii at Manoa. WRRC technical report, 144.
Series/Report no.: WRRC Technical Report
Abstract: The quality of natural and induced storm runoff was ascertained from the 11.33 x 10^6 m^2 (2800 acre) Honolulu International Airport (daily average air traffic volume of about 1000 planes and a mean annual rainfall of approximately 508 mm [20 in.]) by incorporating two monitoring schemes, the wet season and the dry season. The wet-season monitoring involved collecting storm runoff samples during and following rainfall events at established airport sites on paved surfaces. The dry-season monitoring scheme consisted of enclosing a 1.0-m^2 (10.8-ft^2 ) area, applying deionized water, and then collecting the wash water, leached chemicals, and sediments by a heavy-duty vacuum cleaner. Phenol, mercury, and turbidity exceeded the primary drinking water regulations, while pH, manganese, and total dissolved solids at times exceeded secondary drinking water regulations. Grease and oil concentrations showed a definite decrease from the Terminal Building (service and fueling area) to the outer drainage sites. High technology treatment, costing nearly four times the present cost of municipal water, would be required to meet potable water requirements; however for subpotable use, an equalization basin could be constructed for one-half the cost of municipal water. The 1985 projected water demand volume could be met by recovered storm runoff.
Sponsor: Office of Water Research and Technology, U.S. Department of the Interior Grant/Contract No. 14-34-0001-1113 (A-086-HI, Phase I)
Pages/Duration: vii + 30 pages
Appears in Collections:WRRC Technical Reports

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