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　　Architecture, Sustainable Design

A comprehensive book on the sustainable design of research

laboratories

Today's research laboratories are complex and difficult

building types to design, and making them sustainable adds more

obstacles. Written by members of the well-known firm KlingStubbins,

under the guidance of its Directors of Laboratory Planning,

Engineering, and Sustainability, Sustainable Design of Research

Laboratories represents a multidisciplinary approach to addressing

these challenges.

With the needs of architects, engineers, construction

professionals, and facility owners in mind, this book provides a

road map for sustainable planning, design, construction, and

operations. The book is valuable both to experienced laboratory

designers seeking guidance on sustainable strategies, as well as

professionals versed in sustainable design who want insight into

laboratory applications. With content rich in guidance on

performance strategies, even the most technically oriented reader

will find valuable lessons inside. This book:

Focuses on the links between best sustainable practices and

the specific needs of research laboratories

Provides a number of case studies of the best contemporary

sustainably designed labs, with a focus on architecture and

engineering

Explores the challenges in applying rating systems, including

LEED, to laboratory buildings

Examines unique considerations of sustainable approaches in

leased and renovated laboratories

Includes contributions by experts on approaches to integrated

design, site design, programming, and commissioning

This important book shows how theoretical ideas can be applied

to real-life laboratory projects to create healthier and more

efficient research environments.

Foreword.

Acknowledgements.

Chapter 1 Introduction.

Core Principles.

Site Impacts.

Resources.

People.

Air Quality.

Occupant Comfort.

Access to Environment.

Metrics / Rating / Scorecards - Why Use Them?

BREEAM.

LEED.

Labs21.

ASHRAE Standard 189.

Focus on Energy and Carbon.

Laboratory Types.

Sustainability Categories.

Summary.

Key Concepts.

References.

Chapter 2 Integrated Design: Working Collaboratively to Achieve

Sustainability.

Introduction to Integrated Design.

Sustainability Categories.

Planning and Integrated Design Process.

Assembling the Team.

Communicating Expectations.

Ongoing Interactions.

Traditional Sequential Design vs. Integrated Simultaneous

Design.

Project Tasks in an Integrated Design Process.

Research / Evaluation.

Criteria / Loads.

Orientation and Massing.

Envelope Organization.

Glazed Areas.

External Solar Controls.

High Performance Glazing.

Double-Wall Facades.

Demand-Responsive Facades.

Dynamic Glazing.

Integral Loads.

Integrated Design and Building Information Modeling (BIM).

Smithsonian Tropical Research Institute Research Station.

Site.

Energy Security.

Water and Waste.

Materials.

Design for Adaptability to Future Uses.

Indoor Environment.

Conclusion.

Key Concepts.

Chapter 3 Programming: Laying the Groundwork for a Sustainable

Project.

Introduction.

Sustainability Categories.

Macro Programming.

The Program.

Laboratory Module and NSF/Scientist.

Building Organization.

Building and Floor Plate Efficiency.

Equipment Requirements.

Program Space for Sustainable Operations.

Reduce the Frequency and Scope of Renovations.

Micro Programming.

Temperature and Relative Humidity.

Air Changes.

Hours of Operation.

Redundancy.

Filtering.

Plumbing and Process Piping.

Power.

Lighting.

Exhaust Devices.

Code Classification.

Structural.

Equipment.

Conclusion.

Key Concepts.

References.

Chapter 4 Site Design: Connecting to Local and Regional

Communities.

Introduction.

Sustainability Categories.

General Principals of Sustainable Site Design.

Choosing and Appropriate Site.

Site Assessment Study - Part 1.

Site Assessment Study - Part 2.

Designing a Project to Fit Sustainably on a Site.

Lab Specific Site Design Considerations.

Stormwater Management Techniques.

Below Grade Stormwater Storage Chambers.

Pervious Pavements in Action.

Landscaping Considerations.

Case Study: Boston University Medical Center, BioSquare III,

Boston, MA.

Site Design Strategies.

Case Study: AstraZeneca, R&D Expansion, Waltham, MA.

Site Design Strategy.

Case Study: Arnold Arboretum at Harvard University, Weld Hill

Research and Administration Building, Jamaica Plain, MA.

Geo-Thermal Well Field Design Challenges.

Conclusion.

Key Concepts.

References.

Chapter 5 Laboratory Performance: Simulation, Measurement and

Operating Characteristics.

Sustainability Categories.

Energy Modeling.

Laboratory Energy Estimation Basics.

Energy Modeling Protocols.

Energy Analytics.

Life-Cycle Cost Analysis.

Metering for the Sustainable Laboratory Building.

Introduction to Metering.

What to Meter?

Components of a Metering System.

Metering for the Multi-Tenant Laboratory Building.

Metering in Federal Government Laboratories.

Advancing Metering.

The Laboratory Building Dashboard.

Measurement and Verification.

Introduction to M&V.

The M&V Plan.

M&V Analysis Approach.

Metering to Support M&V.

Comparison of Measured and Forecasted Loads.

Dealing with Uncertainty in M&V.

Preparation of the M&V Report.

Laboratory Building Commissioning.

Retro-commissioning.

Conclusion.

Key concepts.

References.

Chapter 6 Engineering Systems: Reducing What Goes In and What

Comes Out.

Introduction.

Sustainability Categories.

Mechanical and Electrical Demand Reduction.

Heating and Cooling Load Profiling.

Supply Airflow Required to Offset the Cooling Load.

Supply Air Required for Lab Dilution.

Supply Air Needed to Makeup Air to Exhaust Elements.

Lab Driver Characterization.

Perimeter Lab Calculation Example (Interior and Envelope

Loads).

Interior Lab Calculation Example (Internal Heat Gains Only).

Reducing Airflow Demand in Load-Driven Labs.

Reducing Demand with Envelope Improvement.

Reducing Demand Caused by Equipment Heat Gain.

Reducing Demand in Hood-Driven Labs.

Reducing Demand in Air Change-Driven Labs.

Energy-Efficient Systems to Meet the Demand.

Variable Air Volume Operation.

Laboratory Air System Control Technology.

Air Distribution Efficiency.

Underfloor Air Distribution (UFAD).

Chilled Beams.

Glycol Runaround Exhaust Air Energy Recovery.

Heat Pipe Exhaust Air Energy Recovery.

Exhaust Air Energy Recovery by Energy Wheels.

Comparison of Energy Recovery Technologies.

Low Pressure-Drop Air Distribution.

Demand-Controlled Ventilation.

Increase Return Air from Labs.

Passive-Evaporative Downdraft Cooling.

Biowall.

Radiant Heating Systems.

Internal Ventilation Requirements and Design Considerations.

Air Exhaust and Intake Design Considerations.

Exhaust Stack Design.

Exhaust Treatment and Emission Reduction.

Low-Energy Cooling and Heating.

Heat Pump Systems.

Chilled Water Distribution.

Ice Storage and Non-Electric Cooling Technologies.

Optimum Chiller Configuration.

Lake Source Cooling Water.

High Efficiency Condensing Boilers.

Heat Recovery from Boilers.

Active Solar Heating and Cooling.

Refrigerant Selection.

Power Generation and Renewable Energy.

Photovoltaic Arrays.

Wind Turbines.Biomass-Fueled Power Generation.

Landfill-Derived Methane Fueled Generation.

Fuel Cells.

Cogeneration.

Carbon Neutral Laboratory Buildings.

Carbon Footprint Reduction.

Corporate Carbon Emission Initiatives.

Laboratory Water Conservation.

Laboratory Water Demand and Consumption.

Sustainable Water Systems.

Water Supply Concepts.

Waste System Concepts.

System Cleaning and Testing.

Conclusion.

Key Concepts.

References.

Chapter 7 Indoor Environment: The Health and Happiness of

Building Occupants.

Introduction.

Learning from Corporate Workplace Trends.

Costs and Returns.

Indoor Air Quality.

Contaminants During Construction.

Contaminants from Material Offgassing.

Contaminants from Occupancy.

Chemical Safety / Chemical Dispensing.

Separation / Compartmentalization.

Limited Quantity Usage - Dispensing / Centralized 

Storage.Thermal Comfort / Occupant Control.

Access to Exterior Environment / Daylight.

Daylighting in Buildings.

Shaping the Building For Daylighting - Conclusions.

Lighting Design for Laboratories.

Luminaire and System Component Selection.

Integrated Approach to Lighting Design.

Lighting Levels.

Lamp Efficiency and Related Selection Considerations.

Lighting Design Strategies.

Design Impacts on Lighting.

Task Lighting.

Daylighting and Daylight Harvesting.

Laboratory Lighting Controls.

Connections Between Acoustical Considerations and Sustainable

Design for Laboratories.

Noise Control.

Outdoor Noise.

Indoor Noise.

Silencer Applications.

Architectural Acoustics Design.

Acoustical Materials for Laboratories.

Conclusion.

Key Concepts.

References.

Chapter 8 Materials: What is the Sustainable Lab Made Of.

Introduction - What Makes Materials Sustainable?

Sustainability Categories.

Material Reuse / Refurbishment / Downcycling.

Recycled Content and Recyclability of Materials.

Harvesting Practices and Transportation.

Healthy Materials VOCs, Low?Toxicity.

Sustainable Material Sources.

Certifications.

What is Different About Laboratory Materials?

Casework.

Worksurfaces.

Material Selection Metrics

Athena Institute.

Cradle to Cradle.

Living Building Challenge.

BRE Green Guide to Specifications.

ASHRAE 189.

Material Classification.

Flooring.

Wall Finishes.

FRP and PVC Panels.

Reinforced Epoxy Wall Coatings.

High Performance Coatings.

Wall Paint.

Casework.

Ceilings.

Conclusions.

Key Concepts.

References.

Chapter 9 Renovation and Leasing: Alternative Approaches to New

Construction.

Introduction.

Sustainability Categories.

Converting Existing Buildings to Laboratory Use.

Benefits of Converting an Existing Building to Laboratory Use

Compared to New Construction.

Conserving Embodied Energy and Reducing Waste.

Adaptive Reuse and LEED.

Characteristics of a Suitable Existing Building for Conversion

to Laboratory Use.

Evaluation of an Existing Building for Conversion to Laboratory

Use.

Case Study Examples.

NIBRI, Cambridge, MA.

University of DE Brown laboratory - Newark, DE.

Gene Logic - Gaithersburg, MD.

640 Memorial Drive - Cambridge, MD.

Leasing Laboratory Space in Multi-Tenant Buildings.

Sustainability Issues Unique to Multi-Tenant Buildings.

The Landlord’s Motivation.

The Tenant’s Motivation.

Identifying Grants and Rebates.

The LEED Green Building Rating System.

Case Study Examples.

670 Albany Street at BioSquare, Boston, MA.

Renovating Previously Occupied Laboratory Space.

Conclusion.

Key Concepts.

Chapter 10 Conclusion.

　　KlingStubbins is an internationally recognized architecture

and design firm with more than sixty years of experience. Founded

on values of design excellence, technological sophistication, and

client service, KlingStubbins has designed high-performance

research environments since its inception. With offices in

Philadelphia, PA; Cambridge, MA; Raleigh, NC; San Francisco, CA;

Washington, D.C., and Beijing, China the firm has designed

sustainable projects throughout the United States, Europe, the

Middle East, and Asia.

Ellen Sisle, AIA, LEED AP, Director of Laboratory Planning, is

leading the firm's laboratory planning and programming

practice.

　　Paul Leonard, PE, LEED AP, Director of Engineering, has

focused on high-performance design of many building types.

　　Jonathan A. Weiss, AIA, LEED AP, Director of Sustainability,

is responsible for the firm's focus on green building.

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书籍介绍

Intended for architects, lab planners, and engineers, this is a comprehensive book on the sustainable design of research laboratories. Written by a well–known firm, KlingStubbins, which has designed many laboratory buildings, the book will have information on integrated design, site design, programming and planning, building materials, and the interiors of labs. A number of case studies of the best contemporary sustainably designed labs will be included along with examination on how the LEED rating system can be applied to laboratory buildings.