BREATHING WALLS A Biological Approach to Healthy Building Envelope Design and Construction George Swanson Oram Miller Wayne Federer, Editor

Transcription

1 BREATHING WALLS A Biological Approach to Healthy Building Envelope Design and Construction George Swanson Oram Miller Wayne Federer, Editor

2 Table of Contents Disclaimer...iii Acknowledgments...ix Preface...xii Part One. INTRODUCTION...1 Chapter 1. Historical Background...3 Chapter 2. The Origins of Building Biology...11 Chapter 3. Our Offer to the Building Trade...12 Chapter 4. Our View of Green Building...16 Chapter 5. The Twenty-Five Principles of Bau-Biologie...19 Part Two. THE BREATHABLE BUILDING ENVELOPE...21 Chapter 6. Desired Properties of a Wall System Introduction What is a Breathing Wall? Vapor Permeability and Diffusion Hygroscopic Adsorption/Desorption Capillary Absorption/Desorption Thermal Mass, Out sulation and Energy Efficiency Radiant Heat Transfer Structural Integrity Protection from Incoming Radio Frequencies (RF) Natural Materials and Subtle Energies...62 Chapter 7. Water Intrusion and Condensation Problems in Conventional, Energy-Efficient Wood Frame Construction Introduction Mycology The extent of the problem Historical background Why We Recommend No Plastic Vapor Diffusion Retarder Rainwater Intrusion into Wall Cavities...76 v

3 7.7 The Capillarity of Plastic House Wrap The Downsides of Fiberglass as an Insulator Mold Growth from Wet Materials Stored on the Job Site Comparing Conventional and Breathable Wall Systems Conclusion...91 Chapter 8. Breathable Envelope Materials Introduction Earth and Clay Straw and Other Plant Fibers Straw-Clay Wood Concrete Made with Portland Cement Autoclaved Aerated Concrete (AAC) Low-Density Fiber-Cement, Made with Portland Cement Healthy Alternative Cements Low-Density Fiber-Cement, Made with Alternative Cement Magnesium Oxychloride Composite Sheeting European Options Choosing the Right Materials Chapter 9. How to Construct a Breathable, Thermally Massive Envelope Use of Low-Density Fiber-Cement Wall Forms on the Job Site Low-Density Fiber-Cement Wall System Protocol Alternative Protocol for Low-Density Fiber-Cement Wall Forms First-Hand Experiences of Builders Using Low-Density Fiber- Cement Wall Forms How to Use Breathable, Solid Blocks on the Job Site Window Detailing Breathable Finishing Treatments, Above Grade Breathable Waterproofing, Below Grade Chapter 10. Breathable Options for Thin-Wall Construction Introduction Wood Framing Alternatives Magnesia-Based Sheeting on the Construction Site Alternative Wood Frame / MgO Board Protocol Cotton Batting as an Insulation Alternative Cellulose Infill Insulation Magnesia-based Mineral Blown-in Insulation Chapter 11. Slab Introduction Benefits of Using Low-Density Fiber-Cement as a Sub-Slab Material Use of an Air Gap Membrane under a Concrete Slab Radon Mitigation Strategies to Mitigate Concrete Sickness Chapter 12. Foundation vi

4 12.1 Introduction Performance Goals Waterproofing with a Cementitious Parging Layer and External Foundation Drainage Membrane The Physics of Vapor Pressure and Vapor Migration Waterproofing Homes with Hydronic Heating Systems without Forced Air Pressurization Wicking of Moisture from Foundation Footing Crawl Space Considerations Frost-Protected Shallow Foundation Chapter 13. Roof and Attic Introduction Attic Roofing Chapter 14. Additional Design Considerations Introduction Moisture Control (Adjunctive to Breathable Envelope Materials) Ventilation Passive Solar Windows and Doors Heating Healthier Forced-Air Systems Cooling Integration with Ancient and Modern Traditions of Design Chapter 15. Examples of Homes Built with Low-Density Fiber-Cement Wall Forms Part Three. CONSTRUCTION PROTOCOL Chapter 16. Worker and Environmental Protection during Construction Chapter 17. Below-Grade Envelope Slab High Water Table and Radon Control Slab Alternatives to Steel Rebar Foundation and Stem Wall Crawl Space Finishing Within the Basement Chapter 18. Above-Grade Envelope Low-Density Fiber-Cement Wall Forms, Made with Portland Cement Low-Density Fiber-Cement, Made with Alternative Cement Autoclaved Aerated Concrete (AAC) Magnesia-Based Sheeting Alternative Wood-Frame with MgO Board vii

5 18.5 Finishes, Interior and Exterior, for Thick-Wall Envelopes Roofing Part Four. MARKETING CONSIDERATIONS Part Five. CONCLUSION viii