Principles of Heating, Ventilation, and Air Conditioning in Buildings
Machine generated contents note: 1. Introduction to Air-Conditioning Systems2. System Analysis Techniques and the Use of EES3. Thermodynamics and Fluid Flow in HVAC Applications4. Heat Transfer in HVAC Applications5. Psychrometrics for HVAC Applications6. Overview of HVAC Systems7. Thermal Comfort a...
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| Format: | UnknownFormat |
| Sprache: | eng |
| Veröffentlicht: |
Hoboken, NJ
John Wiley & Sons, Inc.
2013
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Tag hinzufügen | Zusammenfassung: | Machine generated contents note: 1. Introduction to Air-Conditioning Systems2. System Analysis Techniques and the Use of EES3. Thermodynamics and Fluid Flow in HVAC Applications4. Heat Transfer in HVAC Applications5. Psychrometrics for HVAC Applications6. Overview of HVAC Systems7. Thermal Comfort and Air Quality8. Weather Data, Statistics, and Processing9. Components of Building Heat Loss and Gain10. Heating and Cooling Loads11. Air Distribution Systems12. Liquid Distribution Systems13. Heat Exchangers for Heating and Cooling Applications14. Cooling Towers and Desiccant Systems15 Vapor-Compression Refrigeration and Air-Conditioning Systems16. Heat Pump Systems17. Thermal Storage18. Building and HVAC Energy Use19. HVAC Control Principles20. Supervisory Control21. Engineering Design Problems. "Heating Ventilation and Air Conditioning by J. W. Mitchell and J. E. Braun provides foundational knowledge for the behavior and analysis of HVAC systems and related devices. The emphasis of this text is on the application of engineering principles that features tight integration of physical descriptions with a software program that allows performance to be directly calculated, with results that provide insight into actual behavior. Furthermore, the text offers more examples, end-of-chapter problems, and design projects that represent situations an engineer might face in practice and are selected to illustrate the complex and integrated nature of an HVAC system or piece of equipment"-- |
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| Beschreibung: | Formerly CIP Uk. - Machine generated contents note: 1. Introduction to Air-Conditioning Systems2. System Analysis Techniques and the Use of EES3. Thermodynamics and Fluid Flow in HVAC Applications4. Heat Transfer in HVAC Applications5. Psychrometrics for HVAC Applications6. Overview of HVAC Systems7. Thermal Comfort and Air Quality8. Weather Data, Statistics, and Processing9. Components of Building Heat Loss and Gain10. Heating and Cooling Loads11. Air Distribution Systems12. Liquid Distribution Systems13. Heat Exchangers for Heating and Cooling Applications14. Cooling Towers and Desiccant Systems15 Vapor-Compression Refrigeration and Air-Conditioning Systems16. Heat Pump Systems17. Thermal Storage18. Building and HVAC Energy Use19. HVAC Control Principles20. Supervisory Control21. Engineering Design Problems. - Includes bibliographical references and index. - Machine generated contents note: 1.Introduction to HVAC Systems -- 1.1.Systems and Definitions -- 1.2.History of Air Conditioning -- 1.3.Trends in Energy Use and Impact -- 1.4.HVAC System Design and Operation -- 1.5.Energy Costs -- 1.6.Book Philosophy and Organization -- 1.7.Units -- 1.8.Summary -- Problems -- 2.System Analysis Techniques and the Use of EES -- 2.1.Introduction -- 2.2.Introduction to EES 19 -- 2.3.Common Problems Encountered when Using EES -- 2.4.Curve Fitting Using EES -- 2.5.Optimization Using EES -- 2.6.Successful Problem Solving Using EES -- 2.7.Summary -- Problems -- 3.Thermodynamics and Fluid Flow in HVAC Applications -- 3.1.Introduction -- 3.2.Conservation of Mass -- 3.3.Conservation of Energy -- 3.4.Thermodynamic Properties of Pure Substances -- 3.5.Thermodynamic Limits on Performance -- 3.6.Thermodynamic Work Relations for Pure Substances -- 3.7.Thermodynamic Relations for Fluid Flow -- 3.8.Energy Loss Mechanisms in Fluid Flow -- 3.9.Summary -- Problems -- 4.Heat Transfer in HVAC Applications -- 4.1.Introduction -- 4.2.Conduction Heat Transfer -- 4.3.Convection Heat Transfer -- 4.4.Thermal Radiation Heat Transfer -- 4.5.Transient Heat Transfer -- 4.6.Combined-Mode Heat Transfer -- 4.7.Summary -- Problems -- 5.Psychrometrics for HVAC Applications -- 5.1.Introduction -- 5.2.Moist Air Properties -- 5.3.The Psychrometric Chart -- 5.4.The Standard Atmosphere -- 5.5.Determining Psychrometric Properties Using EES -- 5.6.Psychrometric Applications -- 5.7.Heat and Mass Transfer for Air-Water Vapor Mixtures -- 5.8.Summary -- Problems -- 6.Overview of HVAC Systems -- 6.1.Introduction -- 6.2.Overview of HVAC Systems and Components -- 6.3.Energy Comparison Between CAV and VAV Systems -- 6.4.HVAC System Performance Calculations -- 6.5.ASHRAE Load Calculation Equations -- 6.6.HVAC System Improvements and Alternatives -- 6.7.Summary -- Problems -- 7.Thermal Comfort and Air Quality -- 7.1.Introduction -- 7.2.Criteria for Occupant Comfort Inside Buildings -- 7.3.Criteria for Indoor Air Quality -- 7.4.Summary -- Problems -- Building Heating and Cooling Loads -- 8.Weather Data, Statistics, and Processing -- 8.1.Introduction -- 8.2.Design Temperature Parameters for HVAC Systems -- 8.3.Ambient Temperature and Humidity Correlations -- 8.4.Degree-Day Data and Correlations -- 8.5.Bin Method Data -- 8.6.Ground Temperature Correlations -- 8.7.Solar Radiation Fundamentals -- 8.8.Clear-Sky Solar Radiation -- 8.9.Weather Records -- 8.10.Summary -- Problems -- 9.Components of Building Heat Loss and Gain -- 9.1.Introduction -- 9.2.Thermal Resistance and Conductance of Building Elements -- 9.3.Heat Flow Through Opaque Exterior Surfaces -- 9.4.Transient Heat Flow Through Building Elements -- 9.5.Heat Flow Through Building Elements -- Transfer Function Approach -- 9.6.Heat Flow Through Building Elements -- Thermal Network Approach -- 9.7.Heat Flow Through Glazing -- 9.8.Energy Flows Due to Ventilation and Infiltration -- 9.9.Internal Thermal Gains -- 9.10.Summary -- Problems -- 10.Heating and Cooling Loads -- 10.1.Introduction -- 10.2.Design Heating Load -- 10.3.Design Sensible Cooling Load Using the Heat Balance Method -- 10.4.The Heat Balance Method Using the Thermal Network Approach -- 10.5.Design Latent Cooling Load -- 10.6.Design Loads Using the Thermal Network Method -- 10.7.Summary -- Problems -- Equipment -- 11.Air Distribution Systems -- 11.1.Introduction -- 11.2.Pressure Drops in Duct Systems -- 11.3.Design Methods for Air Distribution Systems -- 11.4.Fan Characteristics -- 11.5.Interaction Between Fan and Distribution System -- 11.6.Air Distribution in Zones -- 11.7.Heat Losses and Gains for Ducts -- 11.8.Air Leakage from Ducts -- 11.9.Summary -- Problems -- 12.Liquid Distribution Systems -- 12.1.Introduction -- 12.2.Head Loss and Pressure Drop in Liquid Distribution Systems -- 12.3.Water Distribution Systems -- 12.4.Steam Distribution Systems -- 12.5.Pump Characteristics -- 12.6.Heat Loss and Gain for Pipes -- 12.7.Summary -- Problems -- 13.Heat Exchangers for Heating and Cooling Applications -- 13.1.Introduction -- 13.2.Overall Heat Transfer Conductance -- 13.3.Heat Exchanger Thermal Performance -- 13.4.Heating Coil Selection Process -- 13.5.Cooling Coil Processes -- 13.6.Cooling Coil Performance Using a Heat Transfer Analogy -- 13.7.Cooling Coil Selection Procedure -- 13.8.Summary -- Problems -- 14.Cooling Towers and Desiccant Dehumidification Systems -- 14.1.Introduction -- 14.2.Cooling Towers -- 14.3.Cooling Tower Performance using an Analogy to Heat Transfer -- 14.4.Cooling Tower Selection Procedure -- 14.5.Desiccant Dehumidifiers -- 14.6.Desiccant Dehumidification Systems -- 14.7.Summary -- Problems -- 15.Vapor Compression Refrigeration and Air-Conditioning Systems -- 15.1.Introduction -- 15.2.Vapor Compression System -- 15.3.Refrigerants -- 15.4.Vapor Compression System Compressors -- 15.5.Vapor Compression System Performance -- 15.6.Alternative Vapor Compression System Concepts -- 15.7.Summary -- Problems -- 16.Heat Pump Systems -- 16.1.Introduction -- 16.2.Air Source Heat Pumps -- 16.3.Ground Source Heat Pumps -- 16.4.Water Loop Heat Pump Systems -- 16.5.Summary -- Problems -- 17.Thermal Storage Systems -- 17.1.Introduction -- 17.2.Ice Storage Systems -- 17.3.Chilled Water Storage Systems -- 17.4.Cold Air Distribution Systems -- 17.5.Building Thermal Storage -- 17.6.Thermal Storage Control Strategies -- 17.7.Performance Characteristics of Ice Storage Tanks -- 17.8.Selection of Ice Storage Capacity -- 17.9.Summary -- Problems -- Design and Control of HVAC Systems -- 18.Building and HVAC Energy Use -- 18.1.Introduction -- 18.2.Weather Data for Energy Use Calculations -- 18.3.Degree-day Method for Estimation of Heating Energy Use -- 18.4.Bin Method for Estimating Energy Use -- 18.5.Simulation Methods for Estimating Energy Use -- 18.6.Thermal Network Method for Estimating Building Energy Use -- 18.7.Summary -- Problems -- 19.HVAC Control Principles -- 19.1.Introduction -- 19.2.Feedback Control Techniques -- 19.3.Implementation of Local Loop Control -- 19.4.Advanced Control Techniques -- 19.5.Summary -- Problems -- 20.Supervisory Control -- 20.1.Introduction -- 20.2.Introduction to Optimal Operation of HVAC Systems -- 20.3.Optimization Statement for All-Electric Cooling Plants Without Storage -- 20.4.Model-based Optimization Procedure -- 20.5.Quadratic Optimization Procedure -- 20.6.Simplified Control Strategies for System Components -- 20.7.Optimization Statement for All-Electric Cooling Plants with Storage -- 20.8.Simplified Control Strategies for Systems with Storage -- 20.9.Methods for Forecasting Building Loads -- 20.10.Summary -- Problems -- 21.Designing HVAC Systems -- 21.1.Introduction -- 21.2.Design Methodology -- 21.3.Life-Cycle Cost -- 21.4.Rules of Thumb -- 21.5.Design Problems for the Students -- Problems |
| Beschreibung: | xxiii, 600 Seiten Illustrationen, Diagramme 26 cm |
| ISBN: | 9780470624579 978-0-470-62457-9 0470624574 0-470-62457-4 |