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Searching... | 33000000011023 | TJ163.5.B84 S65 2017 | Open Access Book | Book | Searching... |
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Summary
Summary
Net Zero-Energy Buildings have been the object of numerous studies in recent years as various countries have set this performance level as a long-term goal of their energy policies. This book presents a unique study of 30 NZEBs that have been constructed and have had their performance measured for at least 12 months. The study is based upon an international collaborative research initiated by the International Energy Agency - the Solar Heating and Cooling Programme (SHC). It is the first book to evaluate building strategies in houses, educational buildings and offices that have been demonstrated to work in practice. It examines how the design challenges of climate and building type have been addressed, and to what extent the various design approaches have been successful.
This book presents convincing evidence that a careful re-thinking of conventional design norms can achieve a far greater performance benefit than is normally feasible. It identifies `solution sets? that work at the whole building level and at the individual building design challenge level for each climate and building type. In doing so, the book provides guidance as to how to improve the design by learning from these cases.
Unusually for a book of this type it has examples of buildings in what are conventionally labeled "hot" and "cold" climates. A simple process is proposed for the reader to commission the analysis of their own climate to assess not only the conventional measure of how hot or cold or humid it is, but also to assess its suitability to support other NZEB technical challenge solutions sets such as Daylight or Natural Ventilation or comfort based climate conditioning.
Author Notes
Prof. Dr. Franois Garde, University of La Reunion, France
Josef Ayoub, CanmetENERGY, Natural Resources Canada (NRCan), Varennes, Qubec, Canada
Dr. Laura Aelenei, LNEG, Portugal
Prof Dr. Daniel Aelenei, Universidade Nova de Lisboa, Portugal
Dr. Alessandra Scognamiglio, ENEA, Naples, Italy
Table of Contents
About the editors | p. IX |
List of Contributors | p. XIII |
IEA Solar Heating and Cooling Programme | p. XVII |
Foreword | p. XIX |
Acknowledgments | p. XXI |
1 Introduction | p. 1 |
1.1 Why another book on net zero energy buildings? | p. 1 |
1.2 What is a net zero energy building? | p. 2 |
1.2.1 IEA SHC Task 40/EBC Annex52: Towards net zero energy solar buildings | p. 2 |
1.2.2 Target audience: Designers and their clients | p. 3 |
1.3 Structure of this book | p. 5 |
References | p. 6 |
2 Net zero energy building design fundamentals | p. 7 |
2.1 Net zero energy building definition and classification | p. 7 |
2.1.1 Physical boundary | p. 8 |
2.1.2 Balance boundary | p. 10 |
2.1.3 Weighting system | p. 11 |
2.1.4 Normalization | p. 11 |
2.1.5 Balance period | p. 12 |
2.1.6 Balance types | p. 12 |
2.1.7 Further requirements | p. 13 |
2.2 Net ZEB case studies: building, climate and measure classifications | p. 14 |
2.2.1 Climate classification | p. 15 |
2.2.2 Building type classification | p. 16 |
2.2.3 Net ZEB measure classification | p. 16 |
2.3 Net-zero energy strategies and measures | p. 18 |
2.3.1 Passive approach strategies | p. 19 |
2.3.2 Passive measures | p. 21 |
2.3.3 Energy efficiency strategies | p. 25 |
2.3.4 Energy efficiency measures | p. 28 |
2.3.5 Renewable energy system strategies | p. 29 |
2.3.6 Renewable energy measures | p. 32 |
2.4 Summary: solution sets | p. 33 |
2.4.1 Net ZEB solution sets and associated categories | p. 33 |
2.4.2 Other considerations of net ZEB design and solution sets | p. 34 |
References | p. 36 |
3 Net ZEB case study buildings, measures and solution sets | p. 39 |
3.1 Introduction | p. 39 |
3.2 The case study buildings | p. 40 |
3.2.1 Residential buildings | p. 41 |
3.2.2 Non-residential buildings | p. 45 |
3.3 Net ZEB measures | p. 51 |
3.4 Net ZEB measures in case study buildings | p. 53 |
3.4.1 Passive measures | p. 54 |
3.4.2 Energy efficiency measures | p. 65 |
3.4.3 Renewable energy measure | p. 74 |
3.5 Net ZEB measure summaries and solution sets | p. 87 |
3.5.1 Net ZEB measures deployment summaries | p. 87 |
3.5.2 Solution sets in residential buildings | p. 100 |
3.5.3 Solution sets in non-residential buildings | p. 101 |
References | p. 101 |
4 Net ZEB design opportunities and challenges | p. 103 |
4.1 Introduction | p. 103 |
4.2 Architectural design and the net ZEB objective | p. 104 |
4.2.1 Energy balance and building shape | p. 104 |
4.2.2 Renewable energy systems design | p. 108 |
4.3 The integrated design process | p. 113 |
4.3.1 The importance of the brief | p. 113 |
4.3.2 The role of the architect | p. 114 |
4.3.3 Organizational design decision making | p. 114 |
4.3.4 Integrated design process and net ZEBs | p. 115 |
4.4 The influence of renewable energy systems on building design | p. 117 |
4.4.1 Envelope integrated supply options: photovoltaics vs. solar thermal | p. 118 |
4.4.2 Photovoltaics | p. 121 |
4.4.3 Solar thermal | p. 123 |
4.4.4 Photovoltaic - Thermal combined systems | p. 124 |
4.4.5 Wind turbines | p. 126 |
4.5 New design opportunities and existing barriers | p. 129 |
4.5.1 The right to sunshine | p. 129 |
4.5.2 A new idea of building physical footprint | p. 130 |
4.5.3 Listed buildings | p. 132 |
4.5.4 Renovation of post- war period buildings | p. 132 |
4.6 The appearance of future net ZEBs | p. 133 |
4.6.1 Net ZEBs shapes and performances: a typological repertoire | p. 133 |
4.6.2 A new aesthetics driven by net ZEBs | p. 141 |
4.7 Concepts for future cities | p. 141 |
4.7.1 Urbanization versus sprawl: towards net zero energy communities? | p. 142 |
4.7.2 Net ZEBs, smart grids and smart cities | p. 143 |
References | p. 147 |
5 Monitoring and post-occupancy evalution of Net ZEBs | p. 153 |
5.1 Introduction | p. 153 |
5.2 Why monitor building energy and comfort? | p. 154 |
5.2.1 Interests and issues related to monitoring buildings | p. 154 |
5.2.2 Monitoring to improve overall building performance | p. 156 |
5.3 A standard monitoring protocol for Net ZEBs | p. 158 |
5.3.1 Monitoring system planning | p. 160 |
5.3.2 Monitoring system design | p. 162 |
5.3.3 Monitoring system installation | p. 163 |
5.3.4 Monitoring system operation | p. 163 |
5.4 Building energy monitoring protocols | p. 165 |
5.4.1 Energy monitoring protocol | p. 165 |
5.4.2 Case study: energy monitoring at ENERPOS | p. 166 |
5.5 Indoor environmental quality monitoring and post-occupancy evaluation | p. 170 |
5.5.1 Indoor environmental quality (IEQ) monitoring protocol | p. 170 |
5.5.2 Case study: comfort monitoring at ENERPOS | p. 174 |
5.6 Experience from monitoring at 5 Net ZEBs | p. 182 |
5.6.1 Monitoring at 5 case study buildings | p. 182 |
5.6.2 Building management system | p. 186 |
5.6.3 Energy results | p. 187 |
5.6.4 Comfort measurements | p. 190 |
5.6.5 General observations on occupant behavior | p. 190 |
References | p. 191 |
6 Feedback from building designers, engineers and occupants | p. 195 |
6.1 Introduction | p. 195 |
6.2 Lessons learned from the design process | p. 195 |
6.2.1 General observations from the design process | p. 195 |
6.2.2 Design hierarchy | p. 197 |
6.2.3 Motivations | p. 198 |
6.3 Lessons learned from building designers, engineers and occupants | p. 199 |
6.3.1 Passive design | p. 199 |
6.3.2 Energy efficiency | p. 202 |
6.3.3 Renewable energy | p. 205 |
6.3.4 Recommendations | p. 206 |
6.4 Occupant consideration in the design and operation of Net ZEBs | p. 208 |
6.4.1 Effects of the occupant behavior on energy use and comfort | p. 208 |
6.4.2 Automation vs user controls | p. 209 |
6.4.3 Occupant behavior can hinder building performance | p. 210 |
6.4.4 Lessons from occupant behavior in Net ZEBs | p. 211 |
References | p. 215 |
Glossary | p. 217 |
Index | p. 223 |