Marian Keeler,
Keeler,
Prasad Vaidya
John Wiley & Sons
e druk, 2016
9781118881910
Fundamentals of Integrated Design for Sustainable Building, Second Edition
Specificaties
Gebonden, 408 blz.
|
Engels
John Wiley & Sons |
e druk, 2016
ISBN13: 9781118881910
Rubricering
Verwachte levertijd ongeveer 9 werkdagen
Samenvatting
The Fully Updated, Indispensible Study of Sustainable Design Principles
Fundamentals of Integrated Design for Sustainable Building is the first textbook to merge principles, theory, and practice into an integrated workflow. This book introduces the technologies and processes of sustainable design and shows how to incorporate sustainable concepts at every design stage. This comprehensive primer takes an active learning approach that keeps students engaged.
This book dispenses essential information from practicing industry specialists to provide a comprehensive introduction to the future of design. This new second edition includes:
Expansive knowledge from history and philosophy to technology and practice
Fully updated international codes, like the CAL code, and current legislations
Up–to–date global practices, such as the tools used for Life–Cycle Assessment
Thorough coverage of critical issues such as climate change, resiliency, health, and net zero energy building
Extensive design problems, research exercise, study questions, team projects, and discussion questions that get students truly involved with the material
Sustainable design is a responsible, forward–thinking method for building the best structure possible in the most efficient way. Conventional resources are depleting and building professionals are thinking farther ahead. This means that sustainable design will eventually be the new standard and everyone in the field must be familiar with the concepts to stay relevant. Fundamentals of Integrated Design for Sustainable Building is the ideal primer, with complete coverage of the most up to date information.
Specificaties
Inhoudsopgave
Preface xiii
<p>Contributors xv</p>
<p>Acknowledgments xix</p>
<p>CHAPTER 1 The Integrated Building Design Process 1</p>
<p>What Is Integrated Building Design? 1</p>
<p>The Process 1</p>
<p>The Focus Areas: Energy, Resources, and Indoor Environment 6</p>
<p>CHAPTER 2 A History of the Environmental Movements 15</p>
<p>Roots 15</p>
<p>Grassroots Movements 17</p>
<p>The Industrial Revolution 19</p>
<p>The Modern Chemical Revolution 20</p>
<p>Twin Tracks of Environmentalism: Conservation and Preservation Movements 21</p>
<p>The Ecology Movement 24</p>
<p>CHAPTER 3 International Conferences and Treaties 27</p>
<p>The Club of Rome 30</p>
<p>The International Conferences 31</p>
<p>After Kyoto 35</p>
<p>CHAPTER 4 The Emergence of Green Building and Green Building Policy 39</p>
<p>Defining Green Building 40</p>
<p>The Roots of Green Building 42</p>
<p>Environmental Toll 43</p>
<p>Green Building Today44</p>
<p>The History of US Energy Policy 46</p>
<p>Green Building Codes in the United States 49</p>
<p>The Road to Green Codes 51</p>
<p>In Summary 53</p>
<p>CHAPTER 5 Chemicals in the Environment, Buildings, and Humans 55</p>
<p>Emission, Transmission, Deposition, and Immission 55</p>
<p>Pathways of Transmission 61</p>
<p>The Right to Know: Chemical Transparency 63</p>
<p>Green Chemistry and Building Materials 72</p>
<p>Rethinking Building Systems 73</p>
<p>Air Systems 74</p>
<p>CHAPTER 6 Fundamentals of Indoor Air Quality 79</p>
<p>Leon Alevantis, MS, PE, LEED AP</p>
<p>Why Is Good IAQ Important? 79</p>
<p>Contributors to IAQ 80</p>
<p>Types of Indoor Pollutants 81</p>
<p>Pushing the Envelope for IAQ Design 84</p>
<p>CHAPTER 7 Indoor Environmental Quality Issues 93</p>
<p>What Is IEQ? 93</p>
<p>Other IEQ Issues 103</p>
<p>Benefits of Good IEQ 104</p>
<p>CHAPTER 8 How Buildings Use Energy 107</p>
<p>Energy in the Life Cycle of a Building 107</p>
<p>Evolution of Buildings and Its Impact on Energy Consumption 107</p>
<p>Operating Energy Use Patterns 110</p>
<p>Heat and Heat Transfer Modes 111</p>
<p>Climate and Weather 114</p>
<p>Traditional Design Response to Climate 118</p>
<p>Occupant Needs 118</p>
<p>Conclusion 123</p>
<p>CHAPTER 9 Reducing Energy Loads 125</p>
<p>Predesign: Site Selection, Building Size, and Transportation 126</p>
<p>Site Analysis 126</p>
<p>Massing and Orientation 128</p>
<p>Building Envelope 128</p>
<p>Lighting 138</p>
<p>Plug Loads 141</p>
<p>Passive Design 142</p>
<p>Case Study: School in Damascus, Syria 149</p>
<p>CHAPTER 10 Energy–Effi cient HVAC Systems 155</p>
<p>Central versus Decentralized Systems 156</p>
<p>Decentralized Systems 156</p>
<p>Central Heating and Cooling Systems 159</p>
<p>HVAC Controls 165</p>
<p>Domestic Hot Water 167</p>
<p>Thermal Zoning and Impact of Architectural Design 167</p>
<p>Preliminary Design Guidelines 168</p>
<p>CHAPTER 11 Energy Modeling and Measurement 171</p>
<p>Metrics for Energy 171</p>
<p>Site Energy and Source Energy 172</p>
<p>Metering, Submetering, and Benchmarking 173</p>
<p>Energy Modeling 176</p>
<p>Energy Modeling Tools 180</p>
<p>Using Modeling to Drive Integrated Cost Estimation 183</p>
<p>CHAPTER 12 Net Zero Energy and Renewable Energy Systems 187</p>
<p>NZE Definitions 187</p>
<p>On–site Renewable Energy Generation 188</p>
<p>NZE Technical Potential 193</p>
<p>NZEB Design Issues 194</p>
<p>NZE at Community Scale 196</p>
<p>Utility Grid and Distributed Generation 196</p>
<p>NZE in Policy 198</p>
<p>Case Studies 199</p>
<p>CHAPTER 13 Climate Change and Resilience 207</p>
<p>The Science 208</p>
<p>CHAPTER 14 How Buildings Use Resources 223</p>
<p>What Are Natural Resources? 223</p>
<p>CHAPTER 15 Materials Selection and Product Certification 239</p>
<p>The Benefits of Healthy Skepticism 239</p>
<p>Materials Have Multiple Impacts 240</p>
<p>The Bases for Materials Selection 240</p>
<p>Making Contact with Technical Staff 244</p>
<p>Environmental Product Declarations 244</p>
<p>Emissions Testing 245</p>
<p>Product Certification, Rating, or Label 246</p>
<p>Tools: Putting It Together 250</p>
<p>CHAPTER 16 How Built Landscapes and Buildings Contribute to Water Quality and Conservation 259</p>
<p>Jamie Phillips and Kevin Conger, CMG Landscape Architecture The Urban Watershed: Watershed Function 259</p>
<p>National Water Policy 260</p>
<p>Pollutants of Concern in the Landscape 261</p>
<p>Urban Stormwater Management: Low ]Impact Design 263</p>
<p>Site Design: Primary Goals 263</p>
<p>Preservation and Protection of Creeks, Wetlands, and Existing Vegetation 263</p>
<p>Treatment Control BMPs 264</p>
<p>Water Conservation in the Landscape 269</p>
<p>Water Use and Energy Use in Buildings 270</p>
<p>CHAPTER 17 Sustainable Neighborhoods and Communities 275</p>
<p>Aaron Welch, Saneta deVuono–Powell, and Matt Raimi, Raimi + Associates What Are Sustainable Communities? 275</p>
<p>A Brief History of Sustainable Planning 276</p>
<p>History of Conventional Development 276</p>
<p>Components of Sustainable City Planning 287</p>
<p>Conclusion 301</p>
<p>CHAPTER 18 Rating Systems and Practice Tools 303</p>
<p>What Is a Rating or Certification System? 303</p>
<p>Living Building Challenge Mission 309</p>
<p>The WELL Building Standard by Delos 310</p>
<p>Regional Systems 312</p>
<p>Ed Mazria and the 2030 Challenge 315</p>
<p>Practice Tools that Drive the Rating System 316</p>
<p>CHAPTER 19 Life–Cycle Assessment 321</p>
<p>Definitions 322</p>
<p>Standards and Methodology 323</p>
<p>Components 324</p>
<p>CHAPTER 20 Waste Management and the Building Industry 337</p>
<p>Waste Impacts 338</p>
<p>Waste Cycles 339</p>
<p>Defining Waste 340</p>
<p>Waste Streams 340</p>
<p>Hospital Waste 341</p>
<p>Integrated Waste Management 342</p>
<p>Benefits of Construction Waste Management 343</p>
<p>Green Demolition 344</p>
<p>Incineration 346</p>
<p>Waste to Fuel 346</p>
<p>Best Practices 346</p>
<p>Diversion 348</p>
<p>Design for Disassembly 348</p>
<p>Construction Waste Management Plans 350</p>
<p>Other Job ]Site Waste Strategies 350</p>
<p>Zero Waste 353</p>
<p>Glossary 357</p>
<p>Index 363</p>
<p>Contributors xv</p>
<p>Acknowledgments xix</p>
<p>CHAPTER 1 The Integrated Building Design Process 1</p>
<p>What Is Integrated Building Design? 1</p>
<p>The Process 1</p>
<p>The Focus Areas: Energy, Resources, and Indoor Environment 6</p>
<p>CHAPTER 2 A History of the Environmental Movements 15</p>
<p>Roots 15</p>
<p>Grassroots Movements 17</p>
<p>The Industrial Revolution 19</p>
<p>The Modern Chemical Revolution 20</p>
<p>Twin Tracks of Environmentalism: Conservation and Preservation Movements 21</p>
<p>The Ecology Movement 24</p>
<p>CHAPTER 3 International Conferences and Treaties 27</p>
<p>The Club of Rome 30</p>
<p>The International Conferences 31</p>
<p>After Kyoto 35</p>
<p>CHAPTER 4 The Emergence of Green Building and Green Building Policy 39</p>
<p>Defining Green Building 40</p>
<p>The Roots of Green Building 42</p>
<p>Environmental Toll 43</p>
<p>Green Building Today44</p>
<p>The History of US Energy Policy 46</p>
<p>Green Building Codes in the United States 49</p>
<p>The Road to Green Codes 51</p>
<p>In Summary 53</p>
<p>CHAPTER 5 Chemicals in the Environment, Buildings, and Humans 55</p>
<p>Emission, Transmission, Deposition, and Immission 55</p>
<p>Pathways of Transmission 61</p>
<p>The Right to Know: Chemical Transparency 63</p>
<p>Green Chemistry and Building Materials 72</p>
<p>Rethinking Building Systems 73</p>
<p>Air Systems 74</p>
<p>CHAPTER 6 Fundamentals of Indoor Air Quality 79</p>
<p>Leon Alevantis, MS, PE, LEED AP</p>
<p>Why Is Good IAQ Important? 79</p>
<p>Contributors to IAQ 80</p>
<p>Types of Indoor Pollutants 81</p>
<p>Pushing the Envelope for IAQ Design 84</p>
<p>CHAPTER 7 Indoor Environmental Quality Issues 93</p>
<p>What Is IEQ? 93</p>
<p>Other IEQ Issues 103</p>
<p>Benefits of Good IEQ 104</p>
<p>CHAPTER 8 How Buildings Use Energy 107</p>
<p>Energy in the Life Cycle of a Building 107</p>
<p>Evolution of Buildings and Its Impact on Energy Consumption 107</p>
<p>Operating Energy Use Patterns 110</p>
<p>Heat and Heat Transfer Modes 111</p>
<p>Climate and Weather 114</p>
<p>Traditional Design Response to Climate 118</p>
<p>Occupant Needs 118</p>
<p>Conclusion 123</p>
<p>CHAPTER 9 Reducing Energy Loads 125</p>
<p>Predesign: Site Selection, Building Size, and Transportation 126</p>
<p>Site Analysis 126</p>
<p>Massing and Orientation 128</p>
<p>Building Envelope 128</p>
<p>Lighting 138</p>
<p>Plug Loads 141</p>
<p>Passive Design 142</p>
<p>Case Study: School in Damascus, Syria 149</p>
<p>CHAPTER 10 Energy–Effi cient HVAC Systems 155</p>
<p>Central versus Decentralized Systems 156</p>
<p>Decentralized Systems 156</p>
<p>Central Heating and Cooling Systems 159</p>
<p>HVAC Controls 165</p>
<p>Domestic Hot Water 167</p>
<p>Thermal Zoning and Impact of Architectural Design 167</p>
<p>Preliminary Design Guidelines 168</p>
<p>CHAPTER 11 Energy Modeling and Measurement 171</p>
<p>Metrics for Energy 171</p>
<p>Site Energy and Source Energy 172</p>
<p>Metering, Submetering, and Benchmarking 173</p>
<p>Energy Modeling 176</p>
<p>Energy Modeling Tools 180</p>
<p>Using Modeling to Drive Integrated Cost Estimation 183</p>
<p>CHAPTER 12 Net Zero Energy and Renewable Energy Systems 187</p>
<p>NZE Definitions 187</p>
<p>On–site Renewable Energy Generation 188</p>
<p>NZE Technical Potential 193</p>
<p>NZEB Design Issues 194</p>
<p>NZE at Community Scale 196</p>
<p>Utility Grid and Distributed Generation 196</p>
<p>NZE in Policy 198</p>
<p>Case Studies 199</p>
<p>CHAPTER 13 Climate Change and Resilience 207</p>
<p>The Science 208</p>
<p>CHAPTER 14 How Buildings Use Resources 223</p>
<p>What Are Natural Resources? 223</p>
<p>CHAPTER 15 Materials Selection and Product Certification 239</p>
<p>The Benefits of Healthy Skepticism 239</p>
<p>Materials Have Multiple Impacts 240</p>
<p>The Bases for Materials Selection 240</p>
<p>Making Contact with Technical Staff 244</p>
<p>Environmental Product Declarations 244</p>
<p>Emissions Testing 245</p>
<p>Product Certification, Rating, or Label 246</p>
<p>Tools: Putting It Together 250</p>
<p>CHAPTER 16 How Built Landscapes and Buildings Contribute to Water Quality and Conservation 259</p>
<p>Jamie Phillips and Kevin Conger, CMG Landscape Architecture The Urban Watershed: Watershed Function 259</p>
<p>National Water Policy 260</p>
<p>Pollutants of Concern in the Landscape 261</p>
<p>Urban Stormwater Management: Low ]Impact Design 263</p>
<p>Site Design: Primary Goals 263</p>
<p>Preservation and Protection of Creeks, Wetlands, and Existing Vegetation 263</p>
<p>Treatment Control BMPs 264</p>
<p>Water Conservation in the Landscape 269</p>
<p>Water Use and Energy Use in Buildings 270</p>
<p>CHAPTER 17 Sustainable Neighborhoods and Communities 275</p>
<p>Aaron Welch, Saneta deVuono–Powell, and Matt Raimi, Raimi + Associates What Are Sustainable Communities? 275</p>
<p>A Brief History of Sustainable Planning 276</p>
<p>History of Conventional Development 276</p>
<p>Components of Sustainable City Planning 287</p>
<p>Conclusion 301</p>
<p>CHAPTER 18 Rating Systems and Practice Tools 303</p>
<p>What Is a Rating or Certification System? 303</p>
<p>Living Building Challenge Mission 309</p>
<p>The WELL Building Standard by Delos 310</p>
<p>Regional Systems 312</p>
<p>Ed Mazria and the 2030 Challenge 315</p>
<p>Practice Tools that Drive the Rating System 316</p>
<p>CHAPTER 19 Life–Cycle Assessment 321</p>
<p>Definitions 322</p>
<p>Standards and Methodology 323</p>
<p>Components 324</p>
<p>CHAPTER 20 Waste Management and the Building Industry 337</p>
<p>Waste Impacts 338</p>
<p>Waste Cycles 339</p>
<p>Defining Waste 340</p>
<p>Waste Streams 340</p>
<p>Hospital Waste 341</p>
<p>Integrated Waste Management 342</p>
<p>Benefits of Construction Waste Management 343</p>
<p>Green Demolition 344</p>
<p>Incineration 346</p>
<p>Waste to Fuel 346</p>
<p>Best Practices 346</p>
<p>Diversion 348</p>
<p>Design for Disassembly 348</p>
<p>Construction Waste Management Plans 350</p>
<p>Other Job ]Site Waste Strategies 350</p>
<p>Zero Waste 353</p>
<p>Glossary 357</p>
<p>Index 363</p>
