Cooling and heating load calculation manual /
Faye C. McQuiston, Jeffrey D. Spitler.
- 2nd
- American Society of Heating, Refrigerating and Air-Conditioning Engineers, [1992]
Incluye diskette, nš inv. RE0288
CONTENIDO I. Introduction Purpose of Design Load Calculations 1.1 Types of Heat Transfer Rates 1.2 Load Calculation Methods 1.3 Information Required-Input 1.3 Information Required-Output 1.4 Suggestion for Manual Calculations 1.4 II. Transfer Function Method Overview 2.1 Transfer Functions 2.2 Determination of Heat Gains 2.9 Solar Radiation Intensity 2.9 Determination of Heat Gains through Walls and Roofs 2.10 Determination of Heat Gains through Windows 2.12 Heat Gain through Interior Partitions, Floors, and Ceilings 2.13 Heat Gain through Below-Grade Surfaces 2.13 Conversion of Heat Gains into Cooling Load 2.13 Summation of Hourly Cooling Loads 2.14 Heat Extraction Rate and Room Temperature 2.14 III. Weather Data and Design Conditions Indoor Design Conditions 3.1 Outdoor Design Conditions 3.1 Wind Data 3.2 Interpolation between Stations 3.3 Weather-Oriented Design Factors 3.3 Data Related to Underground Structures 3.3 Evaporative Cooling Weather Data 3.3 IV. Heat Transmission Coefficients and Property Data Thermal Properties of Building and Insulation Materials 4.1 Surface Conductances and Resistances 4.1 Thermal Resistance of Air Spaces 4.1 Ceiling Air Spaces 4.2 Overall Transmission Coefficients for Doors 4.2 Overall Transmission Coefficients for Windows and Skylights 4.2 Overall Transmission Coefficients for Below-Grade Walls and Floors 4.2 Transmission Coefficients for Slabs on Grade 4.3 V. Internal Heat Gain People 5.1 Lighting 5.1 Miscellaneous Equipment 5.3 VI. Infiltration Infiltration and Outdoor Ventilation Air Loads 6.1 Pressure Difference Due to Stack Effect 6.2 Pressure Difference Due to Wind Effect 6.3 Pressure Difference Due to Building Pressurization 6.4 Curtain Walllnfiltration per Floor or Room 6.5 Crack Infiltration for Doors and Movable Windows 6.7 Infiltration through Commercial-Type Doors 6.7 Infiltration for Low-Rise Buildings 6.9 VII. Heating Load Outdoor Design Conditions 7.2 Indoor Design Conditions 7.2 Calculation of Heat Losses 7.2 Heat Losses in Air Distribution System 7.3 Auxiliary Heat Sources 7.3 Air Required for Space Heating 7.3 VIII. CLTD/SCL/CLF Method Cooling Load Due to Heat Gain through Walls and Roofs 8.2 Heat Gain through Fenestration 8.3 Cooling Load Due to Internal Heat Gain 8.4 Cooling Load Due to Infiltration 8.7 Heat Gain in Air Distribution System 8.7 Air Quantities 8.8 IX. TETD/TA Method Overview of TETD/TA Method 9.1 Solar Radiation Calculations 9.2 Conduction Heat Gain through Walls and Roofs 9.2 Conduction Heat Gain through Windows 9.4 Internal Heat Gains 9.4 Time Averaging 9.4 Summation of Cooling Loads 9.5 X. Air Systems, Loads, Indoor Air Quality, and Psychrometrics Classical Design Procedures 10.1 Off-Design Conditions 10.10 Apendix A. Transfer Function Methods Overview A.1 Using the TFMTAB Program A.2 Using the Optional Language Disks A.3 Data Structures Used in Electronic Tables A.12 Correction of Cooling Loads Due to Nonstandard Radiative/Convective Split in Heat Gains A.16 Apendix B. Heat Transmission Factors Heat Transmission through Opaque Surfaces B.1 Heat Transfer from Fluid to Surface B.2 Radiation Heat Transfer B.3 Overall Coefficients U B.4 Basement Walls and Floors B.5 Floor Slabs at Grade Level B.5 Apendix C. CLTD/SCL/CLF Method Cooling Load Due to External Surfaces C.1 Cooling Load Due to Internal Loads C.2 Appendix D. Psychrometric Processes-Basic Principles Basic Data and Standard Conditions D.1 Basic Moist Air Processes D.3 Processes Involving Work and Lost Pressure D.9 Heat Transfer in Air Distribution System D.10 Apendix E. Installing programs to Generate Custom Tables