Heating and Cooling of Buildings: Principles and Practice of Energy Efficient Design, Third Edition is structured to provide a rigorous and comprehensive technical foundation and coverage to all the various elements inherent in the design of energy efficient and green buildings. Along with numerous new and revised examples, design case studies, and homework problems, the third edition includes the HCB software along with its extensive website material, which contains a wealth of data to support design analysis and planning. Based around current codes and standards, the Third Edition explores the latest technologies that are central to design and operation of today's buildings. It serves as an up-to-date technical resource for future designers, practitioners, and researchers wishing to acquire a firm scientific foundation for improving the design and performance of buildings and the comfort of their occupants. For engineering and architecture students in undergraduate/graduate classes, this comprehensive textbook:

T. Agami Reddy is SRP Professor of Energy and Environment at Arizona State University with joint faculty appointments with the Design School and the School of Sustainable Engineering and the Built Environment. During his 30 year career, he has also held faculty and research positions at Drexel University, Texas A&M University and Princeton University. He teaches and does research in the areas of sustainable energy systems (green buildings, HVAC&R, solar and resiliency/sustainability) and building energy data analytics. He is the author of two textbooks and has close to 200 refereed journal and conference papers, and several book chapters and technical research reports. He is a licensed mechanical engineer and Fellow of both ASME and ASHRAE. He received the ASHRAE Distinguished Service Award in 2008, and was the recipient of the 2014 Yellott Award from the ASME Solar Energy Division.

Jan F. Kreider has served as a professor of engineering at the University of Colorado at Boulder, and is a founding director of its Joint Center for Energy Management. He received his BSME degree (magna cum laude) from Case Western Reserve University, and his postgraduate degrees from the University of Colorado at Boulder. Dr. Kreider is the author of numerous college textbooks and more than 200 technical articles and reports, and has managed numerous building systems research projects. He is a fellow of the ASME, an active member of ASHRAE, and a winner of ASHRAE's E.K. Campbell Award for excellence in building systems education. He is also the president of a consulting company specializing in energy system design and analysis.

Peter Curtiss received his BSCE degree from Princeton University, and his advanced degrees from the University of Colorado at Boulder. He has served as an adjunct professor, and has worked as an engineering consultant. Dr. Curtiss has he author of over 40 technical journal articles, on subjects ranging from neural network modeling and control of building systems to solar radiation measurement. He has worked at research institutes in Israel, Portugal, and France as well as at a number of private engineering firms.

Ari Rabl has served as a research scientist at the Centre d'Energetique of the l'Ecole de Mines in Paris, as well as research professor at the University of Colorado. He received his PhD in Physics from the University of California at Berkeley, and has worked at the Argonne National Laboratory, the Solar Energy Research Institute, and the Center for Energy and Environmental Studies at Princeton University. Dr. Rabl is the author of more than 50 journal articles, numerous technical reports, and holds 10 patents. He is a member of the American Physical Society and ASHRAE.

Heating and Cooling of Buildings: Principles and Practice of Energy Efficient Design, Third Edition is structured to provide a rigorous and comprehensive technical foundation and coverage to all the various elements inherent in the design of energy efficient and green buildings. Along with numerous new and revised examples, design case studies, and homework problems, the third edition includes the HCB software along with its extensive website material, which contains a wealth of data to support design analysis and planning. Based around current codes and standards, the Third Edition explores the latest technologies that are central to design and operation of today's buildings. It serves as an up-to-date technical resource for future designers, practitioners, and researchers wishing to acquire a firm scientific foundation for improving the design and performance of buildings and the comfort of their occupants. For engineering and architecture students in undergraduate/graduate classes, this comprehensive textbook:

Background to the Building Sector and Energy Use Patterns

A Bit of history

Importance of Buildings in the US Economy and Other Countries

Energy Use Patterns by Building Type and End Use

Roles of Building Energy Professionals and HVAC Design Engineers

Basic Concepts in Economics of Energy Efficiency

Units and Conversions

Order of Magnitude Calculations

Fluid and Thermodynamic Properties

Determining Property Values

Types of flow regimes

Conservation of mass and momentum

First law of thermodynamics

Second law of thermodynamics

Modes of heat transfer

Conduction heat transfer

Convection heat transfer

Radiation heat transfer

Evaporative and moisture transfer

Closure

Indoor environmental quality (IEQ)

Thermal comfort

The perception of comfort

Air quality and indoor contaminants

Control of indoor air quality

Closure

Introduction

Solar movement and basic angles

Solar geometry with respect to local observer

Extra-terrestrial insolation

Effect of atmosphere

ASHRAE clear sky irradiance model

Transposition models for tilted and vertical surfaces

Measured solar radiation data worldwide

Statistical correlation models

Importance and design considerations

Optical properties

Thermal properties

Solar heat gains

External and internal shading

High-Performance glazing

Infiltration and Natural Ventilation

Importance and basic definitions

Infiltration rates across building stock

Basic flow equations

Introduction and types of air flow models

Crack flow equation

Induced pressure differences

Engineering component models for air infiltration

Simplified physical models for single-zone air infiltration

Multizone models

Natural ventilation air flow through large openings

Measuring air infiltration and inter-zone flows

Infiltration heat recovery

Load calculations

Solar air temperature and instantaneous conduction heat gain

Below grade heat transfer

Internal heat gains

Treatment of one zone spaces

Multi-zoning in buildings

Basic concepts

Numerical methods- finite difference

Time series methods for conduction heat gains

Thermal network models

Frequency domain…