ASHRAE AEDG50 LargeHospitals 2012
$61.21
ASHRAE Advanced Energy Design Guide for Large Hospitals: 50% Energy Savings
| Published By | Publication Date | Number of Pages |
| ASHRAE | 2012 | 242 |
Advanced Energy Design Guide for Large Hospitals is the fourth in a series designed to provide recommendations for achieving 50% energy savings over the minimum code requirements of ANSI/ASHRAE/IESNA Standard 90.1-2004. The energy savings target of 50% is the next step toward achieving a net zero energy building, which is defined as a building that, on an annual basis, draws from outside resources equal or less energy than it provides using on-site renewable energy sources. ANSI/ASHRAE/IESNA Standard 90.1-2004 provides the fixed reference point and serves as a consistent baseline and scale for all of the 50% Advanced Energy Design Guides. This Guide was created for a “standard” mid- to large-size hospital, typically at least 100,000 ft2 in size, but the strategies apply to all sizes and classifications of large hospitals. Space types covered include cafeterias and kitchens; conference and office areas; reception and waiting areas; examination and treatment rooms; clean and soiled workrooms; nurse stations; nurseries and patient rooms; operating, procedure and recovery rooms; sterilizer equipment areas; pharmacies and laboratories; triage, trauma, and emergency rooms; physical therapy and radiology/imaging rooms; storage, receiving, and mechanical/electrical/telecom rooms. This Guide does not directly address other, atypical or special-use spaces. The specific energy-saving recommendations are summarized in a single table for each climate zone and allow contractors, consulting engineers, architects, and designers to easily achieve advanced levels of energy savings without detailed energy modeling or analyses. In addition, this Guide provides information on integrated design, including general principles and details by project phase, as a necessary component in achieving 50% energy savings. A chapter on energy modeling and energy-efficient strategies is also included to guide teams who do not wish to follow the specific energy-saving recommendation tables. Those looking for help in implementing the climate-specific recommendations of this Guide will find an expanded section of tips and approaches in the “How to Implement Recommendations” chapter, which are cross referenced with the recommendation tables. Case studies and technical examples throughout the Guide illustrate recommendations and demonstrate the technologies in real-world applications. Keywords: hospitals; advanced energy; net zero energy; 50%
PDF Catalog
| PDF Pages | PDF Title |
|---|---|
| 6 | Contents |
| 9 | Sidebars: Case Studies and Technical E xamples |
| 10 | Acknowledgments |
| 12 | Abbreviations and Acronyms |
| 16 | Foreword: A Message to Healthcare Leaders |
| 18 | Chapter 1: Introduction |
| 20 | Goal of this Guide Scope Project Process for Achieving 50% Energy Savings |
| 22 | Conditions to Promote Health and Comfort |
| 23 | Ventilation and Indoor Air Quality (IAQ) in Hospitals Thermal Comfort Visual Comfort Acoustic Comfort |
| 24 | Energy Modeling Analysis |
| 25 | How to Use this Guide References and Resources |
| 28 | Chapter 2: Integrated Design Introduction |
| 29 | Principles of Integrated Design for Energy Efficiency What Is Integrated Design? |
| 31 | Why Use Integrated Design to Maximize Energy Efficiency? How to Assemble an Integrated Design Project Project Details by Phase |
| 41 | Financial Considerations |
| 43 | References and Resources |
| 44 | Cleveland Clinic: A Case Study Interior Lighting |
| 46 | Exterior Lighting HVAC |
| 50 | Chapter 3: Energy Efficiency Strategies for Integrated Design Introduction Setting Energy Targets |
| 53 | Overview of Design Influences |
| 54 | Building and Site |
| 55 | Climate |
| 60 | Building Configuration |
| 69 | Energy Conservation Measures |
| 70 | Impacts of Space Types on Energy Use and ECMs |
| 72 | Building Envelope |
| 73 | Lighting |
| 78 | Plug and Process Loads HVAC |
| 81 | Building Mechanical Systems |
| 86 | Constrol Strategies |
| 87 | References and Resources |
| 90 | Swedish Issaquah Hospital: A Case Study Integrated Design |
| 92 | Building Envelope and Daylighting HVAC Systems Energy Modeling |
| 94 | Chapter 4: Strategies and Recommendations by Climate Zone Introduction |
| 95 | Climate Zone Recommendations |
| 97 | Climate Zone 1 |
| 100 | Climate Zone 2 |
| 103 | Climate Zone 3 |
| 106 | Climate Zone 4 |
| 109 | Climate Zone 5 |
| 112 | Climate Zone 6 |
| 115 | Climate Zone 7 |
| 118 | Climate Zone 8 |
| 122 | Chapter 5: How to Implement Recommendations Envelope Opaque Envelope Components |
| 131 | Vertical Fenestration |
| 132 | Window Design Guidelines for Thermal Conditions |
| 136 | Window Design Guidelines for Daylighting References and Resources |
| 137 | Daylighting General Recommendations |
| 150 | References and Resources |
| 151 | Electric Lighting Design Interior Lighting |
| 171 | Exterior Lighting |
| 172 | References and Resources |
| 173 | Plug and Process Loads Equipment and Control |
| 176 | Kitchen Equipment and Design |
| 181 | Process Loads |
| 183 | References and Resources |
| 184 | Service Water Heating General Recommendations |
| 186 | References and Resources HVAC Systems and Equipment Space Planning—Critical vs. Noncritical Spaces |
| 187 | HVAC System Types |
| 203 | Air-Side Heat Recovery |
| 222 | References and Resources |
| 224 | Quality Assurance Commissioning |
| 226 | Operations and Maintenance |
| 228 | Measurement and Verification |
| 229 | References and Resources |
| 230 | Additional Bonus Savings Other HVAC Strategies |
| 233 | Renewable Energy |
| 236 | Electrical Distribution Systems |
| 238 | Appendix A: Envelope Thermal Performance Factors |
| 240 | Appendix B: International Climatic Zone Definitions |
| 241 | Definitions References |
