The Resource Integrated absorption refrigeration systems : comparative energy and exergy analyses, Ibrahim Dincer, Tahir Abdul Hussain Ratlamwala

Integrated absorption refrigeration systems : comparative energy and exergy analyses, Ibrahim Dincer, Tahir Abdul Hussain Ratlamwala

Label
Integrated absorption refrigeration systems : comparative energy and exergy analyses
Title
Integrated absorption refrigeration systems
Title remainder
comparative energy and exergy analyses
Statement of responsibility
Ibrahim Dincer, Tahir Abdul Hussain Ratlamwala
Creator
Contributor
Author
Author
Subject
Genre
Language
eng
Summary
This book provides a detailed analysis of absorption refrigeration systems, covering single effect to multi-effect systems and their applications. Both the first and second laws of thermodynamics are discussed in relation to refrigeration systems to show how system performance differs from one law to another. Comparative energy and exergy analyses and assessments of single effect, double effect, triple effect and quadruple effect absorption refrigeration system are performed to illustrate the impact of an increase in the number of effects on system performance. In particular, the second law (exergy) formulation for absorption refrigeration systems, rarely discussed by other works, is covered in detail. Integrated Absorption Refrigeration Systems will help researchers, students and instructors in the formulation of energy and exergy efficiency equations for absorption refrigeration systems
Member of
Cataloging source
IDEBK
http://library.link/vocab/creatorDate
1964-
http://library.link/vocab/creatorName
Dinçer, İbrahim
Dewey number
  • 621.5/6
  • 530
Illustrations
illustrations
Index
index present
LC call number
TP492.5
LC item number
.D559 2016
Literary form
non fiction
Nature of contents
  • dictionaries
  • bibliography
http://library.link/vocab/relatedWorkOrContributorName
Ratlamwala, Tahir Abdul Hussain
Series statement
Green energy and technology,
http://library.link/vocab/subjectName
  • Refrigeration and refrigerating machinery
  • Air conditioning
  • TECHNOLOGY & ENGINEERING
  • Air conditioning
  • Refrigeration and refrigerating machinery
Label
Integrated absorption refrigeration systems : comparative energy and exergy analyses, Ibrahim Dincer, Tahir Abdul Hussain Ratlamwala
Link
https://ezproxy.lib.ou.edu/login?url=http://link.springer.com/10.1007/978-3-319-33658-9
Instantiates
Publication
Copyright
Bibliography note
Includes bibliographical references (pages 259-263) and index
Carrier category
online resource
Carrier category code
  • cr
Carrier MARC source
rdacarrier
Content category
text
Content type code
  • txt
Content type MARC source
rdacontent
Contents
  • 1.4.
  • Classification of Absorption Refrigeration Systems.
  • 1.5.
  • Components of Absorption Refrigeration Systems.
  • 1.5.1.
  • Generator.
  • 1.5.2.
  • Absorber.
  • 1.5.3.
  • Condenser.
  • 1.
  • 1.5.4.
  • Evaporator.
  • 1.5.5.
  • Pump.
  • 1.5.6.
  • Expansion Valve.
  • 1.6.
  • Operating Principle.
  • 1.7.
  • Types of Absorption Refrigeration Systems.
  • Fundamentals of Absorption Refrigeration Systems.
  • 1.7.1.
  • Single Effect Absorption Refrigeration System.
  • 1.7.2.
  • Double Effect Absorption Refrigeration System.
  • 1.7.3.
  • Triple Effect Absorption Refrigeration System.
  • 1.7.4.
  • Multiple Effect Absorption Refrigeration System.
  • 1.8.
  • Heat Sources.
  • 1.1.
  • 1.9.
  • Advantages and Disadvantages.
  • 1.10.
  • Comparison with Other Cooling Systems.
  • 1.10.1.
  • Solar PV Cooling System.
  • 1.10.2.
  • Solar Thermoelectric Cooling System.
  • 1.10.3.
  • Thermomechanical Cooling System.
  • Introduction.
  • 1.10.4.
  • Desiccant Cooling Systems.
  • 1.10.5.
  • Adsorption Cooling System.
  • 1.11.
  • Absorption Heat Pumps.
  • 1.12.
  • Closing Remarks
  • 1.2.
  • Absorption Process.
  • 1.3.
  • Absorbents and Refrigerants.
  • 2.2.2.
  • Generator.
  • 2.2.3.
  • Condenser.
  • 2.2.4.
  • Evaporator.
  • 2.2.5.
  • Absorber.
  • 2.2.6.
  • Expansion Valve.
  • 2.
  • 2.2.7.
  • Coefficient of Performance.
  • 2.3.
  • Exergoeconomic Analysis.
  • 2.4.
  • Exergoenvironmental Analysis.
  • 2.4.1.
  • Exergoenvironmental Impact Factor.
  • 2.4.2.
  • Exergoenvironmental Impact Coefficient.
  • Thermodynamic Analysis.
  • 2.4.3.
  • Exergoenvironmental Impact Index.
  • 2.4.4.
  • Exergoenvironmental Impact Improvement.
  • 2.4.5.
  • Exergetic Stability Factor.
  • 2.4.6.
  • Exergetic Sustainability Index.
  • 2.5.
  • Optimization.
  • 2.1.
  • 2.6.
  • Closing Remarks.
  • References
  • Introduction.
  • 2.2.
  • Energy and Exergy Analyses.
  • 2.2.1.
  • Pump.
  • 3.4.
  • Exergoeconomic Analysis.
  • 3.5.
  • Exergoenvironmental Analysis.
  • 3.6.
  • Optimization.
  • 3.7.
  • Illustrative Example.
  • 3.8.
  • Closing Remarks
  • 3.
  • Single Effect Absorption Refrigeration System.
  • 3.1.
  • Introduction.
  • 3.2.
  • System Description.
  • 3.3.
  • Energy and Exergy Analyses.
  • 4.4.
  • Exergoeconomic Analysis.
  • 4.5.
  • Exergoenvironmental Analysis.
  • 4.6.
  • Optimization.
  • 4.7.
  • Illustrative Example.
  • 4.8.
  • Closing Remarks
  • 4.
  • Double Effect Absorption Refrigeration System.
  • 4.1.
  • Introduction.
  • 4.2.
  • System Description.
  • 4.3.
  • Energy and Exergy Analyses.
  • 5.4.
  • Exergoeconomic Analysis.
  • 5.5.
  • Exergoenvironmental Analysis.
  • 5.6.
  • Optimization.
  • 5.7.
  • Illustrative Example.
  • 5.8.
  • Closing Remarks
  • 5.
  • Triple Effect Absorption Refrigeration System.
  • 5.1.
  • Introduction.
  • 5.2.
  • System Description.
  • 5.3.
  • Energy and Exergy Analyses.
  • 6.4.
  • Exergoeconomic Analysis.
  • 6.5.
  • Exergoenvironmental Analysis.
  • 6.6.
  • Optimization Study.
  • 6.7.
  • Illustrative Example.
  • 6.8.
  • Closing Remarks
  • 6.
  • Quadruple Effect Absorption Refrigeration System.
  • 6.1.
  • Introduction.
  • 6.2.
  • System Description.
  • 6.3.
  • Energy and Exergy Analyses.
  • 7.4.
  • Case Study 3: Geothermal-Based Multigeneration System.
  • 7.5.
  • Case Study 4: Geothermal-Based Integrated System for.
  • Standalone Building Needs.
  • 7.6.
  • Closing Remarks
  • 7.
  • Integrated Absorption Refrigeration Systems: Case Studies.
  • 7.1.
  • Introduction.
  • 7.2.
  • Case Study 1: Geothermal-Based Power, Cooling, and Liquefied Hydrogen Generation System.
  • 7.3.
  • Case Study 2: Solar-Based Integrated Absorption Refrigeration and Desalination System for Cooling and Fresh Water Production.
  • 8.4.
  • Biomass-Based Multigeneration Systems.
  • 8.5.
  • Fossil Fuels-Based Multigeneration System.
  • 8.6.
  • Novel ARS-Based Combined Heating and Power Generation Systems.
  • 8.7.
  • Novel ARS Designs.
  • 8.8.
  • Advanced Numerical and Optimization Studies of ARS.
  • 8.
  • 8.9.
  • Novel Working Mixtures.
  • 8.10.
  • Closing Remarks
  • Developments in Absorption Refrigeration Systems.
  • 8.1.
  • Introduction.
  • 8.2.
  • Advanced Solar-Based Absorption Refrigeration Systems.
  • 8.3.
  • Solid Oxide Fuel Cell-Based Multigeneration Systems.
Extent
1 online resource (xvii, 270 pages)
Form of item
online
Isbn
9783319336589
Media category
computer
Media MARC source
rdamedia
Media type code
  • c
Note
SpringerLink
Other physical details
illustrations (some color).
Specific material designation
remote
Stock number
949693
System control number
  • (OCoLC)957318311
  • (OCoLC)ocn957318311
Label
Integrated absorption refrigeration systems : comparative energy and exergy analyses, Ibrahim Dincer, Tahir Abdul Hussain Ratlamwala
Link
https://ezproxy.lib.ou.edu/login?url=http://link.springer.com/10.1007/978-3-319-33658-9
Publication
Copyright
Bibliography note
Includes bibliographical references (pages 259-263) and index
Carrier category
online resource
Carrier category code
  • cr
Carrier MARC source
rdacarrier
Content category
text
Content type code
  • txt
Content type MARC source
rdacontent
Contents
  • 1.4.
  • Classification of Absorption Refrigeration Systems.
  • 1.5.
  • Components of Absorption Refrigeration Systems.
  • 1.5.1.
  • Generator.
  • 1.5.2.
  • Absorber.
  • 1.5.3.
  • Condenser.
  • 1.
  • 1.5.4.
  • Evaporator.
  • 1.5.5.
  • Pump.
  • 1.5.6.
  • Expansion Valve.
  • 1.6.
  • Operating Principle.
  • 1.7.
  • Types of Absorption Refrigeration Systems.
  • Fundamentals of Absorption Refrigeration Systems.
  • 1.7.1.
  • Single Effect Absorption Refrigeration System.
  • 1.7.2.
  • Double Effect Absorption Refrigeration System.
  • 1.7.3.
  • Triple Effect Absorption Refrigeration System.
  • 1.7.4.
  • Multiple Effect Absorption Refrigeration System.
  • 1.8.
  • Heat Sources.
  • 1.1.
  • 1.9.
  • Advantages and Disadvantages.
  • 1.10.
  • Comparison with Other Cooling Systems.
  • 1.10.1.
  • Solar PV Cooling System.
  • 1.10.2.
  • Solar Thermoelectric Cooling System.
  • 1.10.3.
  • Thermomechanical Cooling System.
  • Introduction.
  • 1.10.4.
  • Desiccant Cooling Systems.
  • 1.10.5.
  • Adsorption Cooling System.
  • 1.11.
  • Absorption Heat Pumps.
  • 1.12.
  • Closing Remarks
  • 1.2.
  • Absorption Process.
  • 1.3.
  • Absorbents and Refrigerants.
  • 2.2.2.
  • Generator.
  • 2.2.3.
  • Condenser.
  • 2.2.4.
  • Evaporator.
  • 2.2.5.
  • Absorber.
  • 2.2.6.
  • Expansion Valve.
  • 2.
  • 2.2.7.
  • Coefficient of Performance.
  • 2.3.
  • Exergoeconomic Analysis.
  • 2.4.
  • Exergoenvironmental Analysis.
  • 2.4.1.
  • Exergoenvironmental Impact Factor.
  • 2.4.2.
  • Exergoenvironmental Impact Coefficient.
  • Thermodynamic Analysis.
  • 2.4.3.
  • Exergoenvironmental Impact Index.
  • 2.4.4.
  • Exergoenvironmental Impact Improvement.
  • 2.4.5.
  • Exergetic Stability Factor.
  • 2.4.6.
  • Exergetic Sustainability Index.
  • 2.5.
  • Optimization.
  • 2.1.
  • 2.6.
  • Closing Remarks.
  • References
  • Introduction.
  • 2.2.
  • Energy and Exergy Analyses.
  • 2.2.1.
  • Pump.
  • 3.4.
  • Exergoeconomic Analysis.
  • 3.5.
  • Exergoenvironmental Analysis.
  • 3.6.
  • Optimization.
  • 3.7.
  • Illustrative Example.
  • 3.8.
  • Closing Remarks
  • 3.
  • Single Effect Absorption Refrigeration System.
  • 3.1.
  • Introduction.
  • 3.2.
  • System Description.
  • 3.3.
  • Energy and Exergy Analyses.
  • 4.4.
  • Exergoeconomic Analysis.
  • 4.5.
  • Exergoenvironmental Analysis.
  • 4.6.
  • Optimization.
  • 4.7.
  • Illustrative Example.
  • 4.8.
  • Closing Remarks
  • 4.
  • Double Effect Absorption Refrigeration System.
  • 4.1.
  • Introduction.
  • 4.2.
  • System Description.
  • 4.3.
  • Energy and Exergy Analyses.
  • 5.4.
  • Exergoeconomic Analysis.
  • 5.5.
  • Exergoenvironmental Analysis.
  • 5.6.
  • Optimization.
  • 5.7.
  • Illustrative Example.
  • 5.8.
  • Closing Remarks
  • 5.
  • Triple Effect Absorption Refrigeration System.
  • 5.1.
  • Introduction.
  • 5.2.
  • System Description.
  • 5.3.
  • Energy and Exergy Analyses.
  • 6.4.
  • Exergoeconomic Analysis.
  • 6.5.
  • Exergoenvironmental Analysis.
  • 6.6.
  • Optimization Study.
  • 6.7.
  • Illustrative Example.
  • 6.8.
  • Closing Remarks
  • 6.
  • Quadruple Effect Absorption Refrigeration System.
  • 6.1.
  • Introduction.
  • 6.2.
  • System Description.
  • 6.3.
  • Energy and Exergy Analyses.
  • 7.4.
  • Case Study 3: Geothermal-Based Multigeneration System.
  • 7.5.
  • Case Study 4: Geothermal-Based Integrated System for.
  • Standalone Building Needs.
  • 7.6.
  • Closing Remarks
  • 7.
  • Integrated Absorption Refrigeration Systems: Case Studies.
  • 7.1.
  • Introduction.
  • 7.2.
  • Case Study 1: Geothermal-Based Power, Cooling, and Liquefied Hydrogen Generation System.
  • 7.3.
  • Case Study 2: Solar-Based Integrated Absorption Refrigeration and Desalination System for Cooling and Fresh Water Production.
  • 8.4.
  • Biomass-Based Multigeneration Systems.
  • 8.5.
  • Fossil Fuels-Based Multigeneration System.
  • 8.6.
  • Novel ARS-Based Combined Heating and Power Generation Systems.
  • 8.7.
  • Novel ARS Designs.
  • 8.8.
  • Advanced Numerical and Optimization Studies of ARS.
  • 8.
  • 8.9.
  • Novel Working Mixtures.
  • 8.10.
  • Closing Remarks
  • Developments in Absorption Refrigeration Systems.
  • 8.1.
  • Introduction.
  • 8.2.
  • Advanced Solar-Based Absorption Refrigeration Systems.
  • 8.3.
  • Solid Oxide Fuel Cell-Based Multigeneration Systems.
Extent
1 online resource (xvii, 270 pages)
Form of item
online
Isbn
9783319336589
Media category
computer
Media MARC source
rdamedia
Media type code
  • c
Note
SpringerLink
Other physical details
illustrations (some color).
Specific material designation
remote
Stock number
949693
System control number
  • (OCoLC)957318311
  • (OCoLC)ocn957318311

Library Locations

  • Architecture LibraryBorrow it
    Gould Hall 830 Van Vleet Oval Rm. 105, Norman, OK, 73019, US
    35.205706 -97.445050
  • Bizzell Memorial LibraryBorrow it
    401 W. Brooks St., Norman, OK, 73019, US
    35.207487 -97.447906
  • Boorstin CollectionBorrow it
    401 W. Brooks St., Norman, OK, 73019, US
    35.207487 -97.447906
  • Chinese Literature Translation ArchiveBorrow it
    401 W. Brooks St., RM 414, Norman, OK, 73019, US
    35.207487 -97.447906
  • Engineering LibraryBorrow it
    Felgar Hall 865 Asp Avenue, Rm. 222, Norman, OK, 73019, US
    35.205706 -97.445050
  • Fine Arts LibraryBorrow it
    Catlett Music Center 500 West Boyd Street, Rm. 20, Norman, OK, 73019, US
    35.210371 -97.448244
  • Harry W. Bass Business History CollectionBorrow it
    401 W. Brooks St., Rm. 521NW, Norman, OK, 73019, US
    35.207487 -97.447906
  • History of Science CollectionsBorrow it
    401 W. Brooks St., Rm. 521NW, Norman, OK, 73019, US
    35.207487 -97.447906
  • John and Mary Nichols Rare Books and Special CollectionsBorrow it
    401 W. Brooks St., Rm. 509NW, Norman, OK, 73019, US
    35.207487 -97.447906
  • Library Service CenterBorrow it
    2601 Technology Place, Norman, OK, 73019, US
    35.185561 -97.398361
  • Price College Digital LibraryBorrow it
    Adams Hall 102 307 West Brooks St., Norman, OK, 73019, US
    35.210371 -97.448244
  • Western History CollectionsBorrow it
    Monnet Hall 630 Parrington Oval, Rm. 300, Norman, OK, 73019, US
    35.209584 -97.445414
Processing Feedback ...