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003    OCoLC
005    20141212055628.0
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029 1  AU@ |b000001946974
035    (Sirsi) o08016152
035    (OCoLC)8016152
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074    429-T-4
082 04 621.31242 |bqC559, 80-85121
086 0  E 1.28:SERI/TR-332-416/v.-
100 1  Chum, Helena L. |=^A971175
245 10 Review of thermally regenerative electrochemical systems / |cHelena L. Chum, Robert A. Osteryoung ; prepared for the U.S. Department of Energy.
246 3  Thermally regenerative electrochemical systems
256    Electronic data (2 PDF files : 1.6 Mb and 3.8 MB).
260    Golden, Colo. : |bSolar Energy Research Institute ;Springfield, VA : |bAvailable from National Technical Information Service, |c1981-
300    <1> volumes : |billustrations ; |c28 cm.
336    text |2rdacontent
337    unmediated |2rdamedia
338    volume |2rdacarrier
490 0  SERI/TR ; |v332-416
500    "State University of New York at Buffalo."
500    "August 1980"--Vol. 1.
500    "April 1981"--Vol. 2.
504    Includes bibliographical references.
500    Also available via Internet in .pdf format. Adobe Acrobat Reader required.
505 0  v. 1. Synopsis and executive summary -- v. 2. [No distinctive title].
520 3  Thermally regenerative electrochemical systems (TRES) are closed systems that convert heat in to electricity in an electrochemical heat engine that is Carnot cycle limited in efficiency. Past and present work on such systems is reviewed. Two broad classes of TRES are based on the types of energy inputs required for regeneration: thermal alone and coupled thermal and electrolytic. The thermal regeneration alone encompasses electrochemical systems (galvanic or fuel cells) in which one or more products are formed. The regeneration can be performed in single or multiple steps. The compounds include metal hydrides, halides, oxides, chalcogenides, and alloys or bimetallic systems. The coupled thermal and electrolytic regeneration encompasses electrochemical systems (galvanic or fuel cells) regenerated by electrolysis at a different temperature or different pressure . Examples include metal halides and water. Thermogalvanic or nonisothermal cells are included in this category. Also included are electrochemical engines in which the working electroactive fluid is isothermally expanded through an electrolyte. TRES cover temperature ranges from about 20°C to 1000°C. Engines with power outputs of 0.1 mW / cm² to 1 W / cm² have been demonstrated. Recommendations are made of areas of research in science and engineering that would have long-range benefit to a TRES program.
588    Description based on: Vol. 2.
650  0 Fuel cells. |=^A24215
650  0 Electric power production from chemical action. |=^A1156155
650  7 Eletroquimica. |2larpcal
700 1  Osteryoung, Robert Allen, |d1927- |=^A1148170
710 2  Solar Energy Research Institute. |=^A117649
710 1  United States. |bDepartment of Energy. |=^A634277
710 2  State University of New York at Buffalo. |=^A169026
776 08  |iOnline version:Chum, Helena L. |tReview of thermally regenerative electrochemical systems. |dGolden, Colo. : Solar Energy Research Institute ; Springfield, VA : Available from National Technical Information Service, 1981- |w(OCoLC)759241364
856 41  |uhttp://www.nrel.gov/docs/legosti/old/416_v1.pdf
856 41  |uhttp://www.nrel.gov/docs/legosti/old/416_v2.pdf
949    E 1.28:SERI/TR-332-416/v. 1 |wSUDOC |hJOYNER38 |ojlhb |i30372016229673
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