Absorption heating technologies : efficient heating, heat recovery and renewable energy /: efficient heating, heat recovery and renewable energy. (©2020)
- Record Type:
- Book
- Title:
- Absorption heating technologies : efficient heating, heat recovery and renewable energy /: efficient heating, heat recovery and renewable energy. (©2020)
- Main Title:
- Absorption heating technologies : efficient heating, heat recovery and renewable energy
- Further Information:
- Note: Wei Wu, Xianting Li, Tian You.
- Other Names:
- Wu, Wei
Li, Xianting
You, Tian - Contents:
- Intro; Contents; 1 Characteristics of Conventional Heating Technologies; Abstract; 1.1 Problems of Existing Heating Technologies; 1.1.1 Energy Consumption of Heating Applications; 1.1.2 Existing Heating Systems and Problems; 1.2 Efficient Fuel-Based Heating Technologies; 1.2.1 Boiler Enhancement and Replacement; 1.2.2 Heat Recovery from Cogeneration; 1.2.3 Flue Gas Waste Heat Recovery; 1.3 Vapor-Compression Heating Technologies; 1.3.1 Air Source Heat Pump (ASHP); 1.3.2 Ground Source Heat Pump (GSHP); 1.4 Summary; References; 2 Fundamentals of Absorption Heating Technologies; Abstract 2.1 Basic Principles of Efficient Heating Technologies2.1.1 Problems of Conventional Heating Systems; 2.1.2 Efficient Energy Utilization Principles; 2.2 Principles of Various Absorption Heating Technologies; 2.2.1 Absorption Heat Increasing; 2.2.2 Absorption Heat Shifting; 2.2.3 Absorption Temperature Upgrading; 2.2.4 Absorption Temperature Adapting; 2.3 Working Fluids for Absorption Heating Technologies; 2.3.1 General Features of Various Working Fluids; 2.3.2 High Evaporation Temperature Application; 2.3.3 Low Evaporation Temperature Application 2.4 Modeling Methods for Absorption Heating Cycles2.4.1 Ideal Equivalent Model; 2.4.2 Actual Thermodynamic Model; References; 3 Low Evaporation Temperature Absorption Heat Pump; Abstract; 3.1 Principles of Low Evaporation Temperature AHP Heating; 3.1.1 Basic Idea of Low Evaporation Temperature AHP Heating; 3.1.2 Configurations of Low EvaporationIntro; Contents; 1 Characteristics of Conventional Heating Technologies; Abstract; 1.1 Problems of Existing Heating Technologies; 1.1.1 Energy Consumption of Heating Applications; 1.1.2 Existing Heating Systems and Problems; 1.2 Efficient Fuel-Based Heating Technologies; 1.2.1 Boiler Enhancement and Replacement; 1.2.2 Heat Recovery from Cogeneration; 1.2.3 Flue Gas Waste Heat Recovery; 1.3 Vapor-Compression Heating Technologies; 1.3.1 Air Source Heat Pump (ASHP); 1.3.2 Ground Source Heat Pump (GSHP); 1.4 Summary; References; 2 Fundamentals of Absorption Heating Technologies; Abstract 2.1 Basic Principles of Efficient Heating Technologies2.1.1 Problems of Conventional Heating Systems; 2.1.2 Efficient Energy Utilization Principles; 2.2 Principles of Various Absorption Heating Technologies; 2.2.1 Absorption Heat Increasing; 2.2.2 Absorption Heat Shifting; 2.2.3 Absorption Temperature Upgrading; 2.2.4 Absorption Temperature Adapting; 2.3 Working Fluids for Absorption Heating Technologies; 2.3.1 General Features of Various Working Fluids; 2.3.2 High Evaporation Temperature Application; 2.3.3 Low Evaporation Temperature Application 2.4 Modeling Methods for Absorption Heating Cycles2.4.1 Ideal Equivalent Model; 2.4.2 Actual Thermodynamic Model; References; 3 Low Evaporation Temperature Absorption Heat Pump; Abstract; 3.1 Principles of Low Evaporation Temperature AHP Heating; 3.1.1 Basic Idea of Low Evaporation Temperature AHP Heating; 3.1.2 Configurations of Low Evaporation Temperature AHP; 3.2 Performance Characteristics of ASAHP; 3.2.1 Effect of Driving Source Temperature; 3.2.2 Effect of Ambient Air Temperature; 3.2.3 Effect of Produced Hot Water Temperature; 3.3 Experimental Investigation of NH3/H2O AHP 3.3.1 Experiment Prototype3.3.2 Performance Under Standard Working Condition; 3.3.3 Performance Under Various Working Conditions; 3.3.4 Performance Under Various Adjustment Methods; 3.4 Merits of Low Evaporation Temperature AHP Heating; 3.4.1 Heating Performance; 3.4.2 Emission Characteristics; References; 4 Performance Improvement of Absorption Heat Pump; Abstract; 4.1 Theoretical Improvement for Colder Ambient Conditions; 4.1.1 Principles of Different Advanced Cycles; 4.1.2 Comparison and Selection of Advanced Cycles; 4.1.3 Annual Energy Analysis of the Best Solution 4.2 Experimental Improvement for Colder Ambient Conditions4.2.1 Performance Under Typical Conditions; 4.2.2 Performance Under Various Ambient Conditions; 4.3 Theoretical Improvement for Lower Driving Temperatures; 4.3.1 Performance of Different Advanced Cycles; 4.3.2 Comparison and Selection of Advanced Cycles; 4.3.3 Annual Energy Analysis of the Best Solution; 4.4 Experimental Improvement for Lower Driving Temperatures; 4.5 Improvement for Higher Driving Temperatures; 4.5.1 Generator Absorber Heat Exchange (GAX); 4.5.2 Compression-Assisted GAX; 4.5.3 Annual Energy Analysis of the GAX Cycles … (more)
- Publisher Details:
- Singapore : Springer
- Publication Date:
- 2020
- Copyright Date:
- 2020
- Extent:
- 1 online resource (270 pages)
- Subjects:
- 536/.3
Heat -- Radiation and absorption
Radiative transfer
Heat -- Radiation and absorption
Radiative transfer
Electronic books - Languages:
- English
- ISBNs:
- 9789811504709
9811504709 - Related ISBNs:
- 9811504695
9789811504693 - Notes:
- Note: Includes bibliographical references.
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- Legal Deposit; Only available on premises controlled by the deposit library and to one user at any one time; The Legal Deposit Libraries (Non-Print Works) Regulations (UK).
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