Record Display for the EPA National Library Catalog

RECORD NUMBER: 10 OF 20

Main Title Design guidelines for agricultural soil warming systems utilizing waste heat /
Author Slegel, David L.,
CORP Author Environmental Research Lab., Corvallis, Oreg. Assessment and Criteria Development Div.
Publisher U.S. Environmental Protection Agency, Office of Research and Development, Corvallis Environmental Research Laboratory, Assessment and Criteria Development Division, for sale by the National Technical Information Service,
Year Published 1976
Report Number EPA-600/3-76-026
Stock Number PB-252 251
OCLC Number 02326323
ISBN pbk.
Subjects Heat-transfer media ; Soil temperature--United States ; Waste heat ; heat loss
Additional Subjects Soils ; Heating ; Waste water reuse ; Irrigation ; Cooling water ; Thermal pollution ; Soil water ; Pipes ; Temperature ; Depth ; Weather ; Moisture content ; Frost protection ; Heat transfer ; Atmospheric temperature ; Oregon ; Georgia ; Minnesota ; Soil heating ; Portland(Oregon) ; Athens(Georgia) ; Saint Paul(Minnesota)
Internet Access
Description Access URL
https://nepis.epa.gov/Exe/ZyPDF.cgi?Dockey=2000WO8L.PDF
Holdings
Library Call Number Additional Info Location Last
Modified
Checkout
Status
EJBD  EPA 600-3-76-026 Headquarters Library/Washington,DC 03/11/2014
EKBD  EPA-600/3-76-026 Research Triangle Park Library/RTP, NC 04/15/2013
ELBD ARCHIVE EPA 600-3-76-026 Received from HQ AWBERC Library/Cincinnati,OH 10/04/2023
ELBD  EPA 600-3-76-026 AWBERC Library/Cincinnati,OH 04/10/1998
ESAD  EPA 600-3-76-026 Region 10 Library/Seattle,WA 03/23/2010
NTIS  PB-252 251 Some EPA libraries have a fiche copy filed under the call number shown. 07/26/2022
Collation vi, 31 pages : graphs ; 28 cm.
Abstract
The work was performed to provide potential users of soil warming systems with some general guidelines for the design of a soil warming installation. Although a detailed design is not included, the general configuration of such a system is discussed. A computer program that solves the equations governing heat and water transfer in soils was used to simulate the operation of a soil warming system composed of a series of buried pipes at uniform spacing and depth carrying warm water. The results included temperature and moisture content distributions for various soil warming system pipe spacings and depths and for varying weather conditions. Annual temperature cycles are presented for Portland, Oregon; Athens, Georgia; and St. Paul, Minnesota; for soil with no heating; and for soil with a continuously operating soil warming system.
Notes
Includes bibliographical references (pages 29-30).