| Record ID | marc_columbia/Columbia-extract-20221130-031.mrc:244196192:6045 |
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LEADER: 06045cam a2200733 i 4500
001 15128917
005 20220514233629.0
006 m o d
007 cr cnu---unuuu
008 180120s2018 flu ob 001 0 eng d
035 $a(OCoLC)on1020031519
035 $a(NNC)15128917
040 $aEBLCP$beng$erda$epn$cEBLCP$dN$T$dOCLCQ$dOCLCF$dNLE$dERL$dYDX$dWYU$dOCLCQ$dUKMGB$dOCLCQ$dOCLCO$dK6U$dOCLCO
015 $aGBB818551$2bnb
016 7 $a018694030$2Uk
019 $a1031049130
020 $a9781315305936$q(electronic bk.)
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020 $a9781315305950
020 $a131530595X
020 $a9781315305943
020 $a1315305941
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020 $z9781138033535$q(hbk.)
035 $a(OCoLC)1020031519$z(OCoLC)1031049130
037 $a9781315305936$bIngram Content Group
050 4 $aTJ265
072 7 $aTEC$x009070$2bisacsh
082 04 $a621.4021$223
049 $aZCUA
100 1 $aShah, Yatish T.,$eauthor.
245 10 $aThermal energy :$bsources, recovery, and applications /$cYatish T. Shah.
264 1 $aBoca Raton :$bCRC Press, Taylor & Francis Group,$c[2018]
264 4 $c©2018
300 $a1 online resource (889 pages)
336 $atext$btxt$2rdacontent
337 $acomputer$bc$2rdamedia
338 $aonline resource$bcr$2rdacarrier
490 1 $aSustainable energy strategies
504 $aIncludes bibliographical references and index.
588 0 $aPrint version record.
505 0 $aCover; Half Title; Title Page; Copyright Page; Dedication Page; Table of Contents; Series Preface; Preface; About the Author; Chapter 1: Basics of Macrothermal Energy; 1.1 Introduction; 1.2 Types of Heat; 1.2.1 Sensible Heat; 1.2.2 Latent Heat; 1.2.2.1 Types of Latent Heat; 1.2.2.2 Phase Transition; 1.2.2.2.1 Boiling; 1.2.2.2.2 Condensation; 1.2.2.2.3 Melting; 1.2.2.3 Latent Heat for Condensation of Water; 1.2.3 Heat Associated with Physical and Chemical Processes (Bond Energy); 1.2.3.1 Heat Associated with Physical Processes; 1.2.3.2 Heat Associated with Chemical Processes.
505 8 $a1.3 Heat-Transfer Mechanisms1.3.1 Conduction; 1.3.1.1 Thermal Conductivity; 1.3.2 Convection; 1.3.3 Radiation; 1.3.4 Insulation and Radiance Resistance; 1.4 Laws of Thermodynamics; 1.4.1 Zeroth Law; 1.4.2 First Law; 1.4.3 Second Law; 1.4.4 Third Law; 1.5 Energy Transformationâ#x80;#x94;Heat Engine and Heat Pump; 1.5.1 Release of Energy from Radioactive Potential; 1.5.2 Release of Energy from Hydrogen Fusion Potential; 1.5.3 Recovery of Underground Energy by Radioactive Decay; 1.5.4 Heat Engines; 1.5.4.1 External Combustion Engines; 1.5.4.2 Internal Combustion Engines.
505 8 $a1.5.5 Heat Engine Performance Enhancements1.5.6 Heat Pumps and Refrigerators; 1.6 Thermodynamic Cycles; 1.6.1 Ideal Carnot Cycle; 1.6.2 Heat and Work Relationship; 1.6.3 State Functions and Entropy; 1.6.4 Types of Power Cycles and Methods of Improvement; 1.6.5 Specific Details of Some Power Cycles; 1.6.5.1 Otto Cycle; 1.6.5.2 Stirling Cycle; 1.6.5.3 The Ericsson Cycle; 1.6.5.4 The Rankine Cycle (Vapor Cycle); 1.6.5.5 The Stoddard Cycle; 1.6.5.6 The Lenoir Cycle; 1.6.5.7 The Atkinson Cycle; 1.6.5.8 The Kalina Cycle; 1.6.5.9 The Miller Cycle; 1.6.5.10 The Diesel Cycle.
505 8 $a1.6.5.11 The Brayton Cycle1.6.5.12 The Bell Coleman Cycle; 1.6.5.13 The Scuderi Cycle; 1.6.5.14 The Hygroscopic Cycle; 1.6.6 Heat Pump and Refrigeration Cycles; 1.6.6.1 Vapor-Compression Cycle; 1.6.6.2 Vapor-Absorption Cycle; 1.6.6.3 Gas Cycle; 1.6.7 Modeling Real Systems; 1.7 Combined Cycle Power Plants; 1.7.1 Single-Shaft versus Multi-Shaft Options; 1.7.2 Integrated Combined Cycles; 1.8 Direct Conversion of Thermal Energy to Electrical Energy; 1.8.1 Thermoelectric Generation; 1.8.1.1 Brief Description of Concepts behind Thermoelectric Generation; 1.8.1.1.1 Thermal Conductivity.
505 8 $a1.8.1.1.2 Electrical Conductivity1.8.1.1.3 State Density; 1.8.1.1.4 Power Factor; 1.8.1.1.5 Device Efficiency; 1.8.1.1.6 Quality Factor; 1.8.1.2 Thermoelectric Materials; 1.8.1.3 Applications of Thermoelectric Generator; 1.8.2 Thermoelectric Coolers; 1.8.3 Thermophotovoltaics; 1.8.3.1 Materials; 1.8.3.2 Applications; 1.8.4 Thermionic Generation; 1.8.5 Thermogalvanic Cell; 1.8.5.1 Aqueous Electrolytes Cell; 1.8.5.2 Nonaqueous Electrolytes Cell; 1.8.5.3 Molten Salts Cell; 1.8.5.4 Solid Electrolytes Cell; 1.9 Combined Heat and Power Generation-Cogeneration and Trigeneration.
500 $a1.9.1 Microcombined Heat and Power.
520 $a"The book details sources of thermal energy, methods of capture, and applications. It describes the basics of thermal energy, including measuring thermal energy, laws of thermodynamics that govern its use and transformation, modes of thermal energy, conventional processes, devices and materials, and the methods by which it is transferred. It covers 8 sources of thermal energy: combustion, fusion (solar) fission (nuclear), geothermal, microwave, plasma, waste heat, and thermal energy storage. In each case, the methods of production and capture and its uses are described in detail. It also discusses novel processes and devices used to improve transfer and transformation processes."--Provided by publisher
650 0 $aThermodynamics.
650 0 $aHeat engineering.
650 2 $aThermodynamics
650 6 $aThermodynamique.
650 6 $aThermique.
650 7 $athermodynamics.$2aat
650 7 $aTECHNOLOGY & ENGINEERING$xMechanical.$2bisacsh
650 7 $aHeat engineering.$2fast$0(OCoLC)fst00953853
650 7 $aThermodynamics.$2fast$0(OCoLC)fst01149832
655 0 $aElectronic books.
655 4 $aElectronic books.
776 08 $iPrint version:$aShah, Yatish T.$tThermal Energy : Sources, Recovery, and Applications.$dMilton : CRC Press, ©2018$z9781138033535
830 0 $aSustainable energy strategies.
856 40 $uhttp://www.columbia.edu/cgi-bin/cul/resolve?clio15128917$zTaylor & Francis eBooks
852 8 $blweb$hEBOOKS