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01.12.2016 | HOT TOPIC

Why and How the Sustainable Building Community Should Embrace Fire Safety

verfasst von: Bonnie C. Roberts, Michael E. Webber, Ofodike A. Ezekoye

Erschienen in: Current Sustainable/Renewable Energy Reports | Ausgabe 3-4/2016

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Abstract

Sustainable building construction is one of the fastest-growing industries in the USA. Changes in materials, products, designs, and methodologies are occurring to accommodate this green progression. While these changes have energy and environmental benefits, questions have been raised about impacts on fire safety. There are two major reasons to consider the nexus of fire safety and sustainable design. First is a concern for the environment and how a building fire would cause environmental harm. It is possible that a single fire event can negate several, if not all, elements of green design. Second is a concern that sustainable design features will cause unintended increased fire risk or hazards. Sustainable design is a relatively new market with some unconventional materials, techniques, and features that have not yet been proven with time, which introduces risk of unintentional consequences. Moving forward, it would be valuable to integrate green design with fire safety such that they reinforce rather than undermine each other. This article seeks to examine the relationship between fire safety and sustainability in buildings, discuss the status of the fire and sustainability communities, and recommend avenues for development and implementation to promote fire-safe sustainable designs. Such avenues include incorporating greywater and rainwater reuse systems with fire sprinklers, fire alerts and controls in building automation systems, better safety mechanisms and designs for on-site energy production and storage, and less combustible and more resilient structural elements and insulation.

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ANSI

American National Standards Institute

ASHRAE

American Society of Heating, Refrigerating and Air-Conditioning Engineers

BAS

Building automation system

BEES

Building for Environmental and Economic Sustainability

BRANZ

Building Research Association of New Zealand

BRE

Building Research Establishment

CEDA

Comprehensive Environmental Data Archive

DESS

Distributed energy storage system

EIO-LCA

Economic Input–Output Life Cycle Assessment

EPA

Environmental Protection Agency

EPD

Environmental Product Declaration

FDS

Fire Dynamics Simulator

Flame retardant

FTC

Federal Trade Commission

GFDI

Ground fault detector and interrupter

GHG

Greenhouse gas

HRRpeak

Peak heat release rate

HVAC

Heating, ventilation, and air conditioning

IBC

International Building Code

ICC

International Code Council

IEQ

Indoor environmental quality

IgCC

International Green Construction Code

ISO

International Organization for Standardization

LCA

Life cycle assessment

LCI

Life cycle inventory

LEED

Leadership in Energy and Environmental Design

LEL

Lightweight engineered lumber

NAHB

National Association of Home Builders

NASFM

National Association of State Fire Marshals

NFIRS

National Fire Incident Reporting System

NFPA

National Fire Protection Association

NFSA

National Fire Sprinkler Association

NGBS

National Green Building Standard

NIBS

National Institute of Building Sciences

NIST

National Institute of Standards and Technology

NRC

National Research Council of Canada

NREL

National Renewable Energy Laboratory

PBD

Performance-based design

Photovoltaic

SMV

Smokeview

Underwriters Laboratories

USGBC

U.S. Green Building Council

WBDG

Whole Building Design Guide

WPI

Worcester Polytechnic Institute

Preservation Green Lab. The greenest building: quantifying the environmental value of building reuse. Tech. Rep.; 2011.

AIA. Local leaders in sustainability: green incentives. Tech. Rep., The American Institute of Architects; 2007.

Meacham B, Poole B, Echeverria J, Cheng R. Fire safety challenges of green buildings. Tech. Rep., The Fire Protection Research Foundation; 2012.

SmartMarket Report. World green building trends: business benefits driving new and retrofit market opportunities in over 60 countries. Tech. Rep.; 2013.

SmartMarket Report. Green multifamily and single family homes: growth in a recovering market. Tech. Rep., McGraw Hill Construction; 2014.

Setar L, Macfarland M. Top 10 fastest-growing industries. Tech. Rep., IBISWorld Inc.; 2012.

EPA. Funding opportunities—green building. 2014. http://archive.epa.gov/greenbuilding/web/html/funding.html. Accessed 12 Sept 2015.

Diment D. Green machine: a rising focus on environmental sustainability will underpin industry growth. Tech. Rep. August, IBISWorld Inc; 2014.

Gritzo L, Doerr W, Bill R, Ali H, Nong S, Krasner L. The influence of risk factors on sustainable development. Tech. Rep., FM Global; 2009.

10.

Wieczorek C, Ditch B, Bill R. Environmental impact of automatic fire sprinklers. Tech. Rep., FM Global; 2010.

11.

National Fire Protection Association. Structure Fires by occupancy 2007–2011 annual averages. Tech. Rep. April. NFPA: Quincy; 2013.

12.

EPA. Greenhouse gas equivalencies calculator. 2014. http://www.epa.gov/cleanenergy/energy-resources/calculator.html. Accessed 06 Dec 2014.

13.

Martin D, Tomida M, Meacham B. The environmental impact of fire. Tech. Rep., The Fire Protection Research Foundation; 2015.

14.

Haynes HJG. Fire loss in the United States during 2014. Tech. Rep. FLX10-REV. National Fire Protection Association: Quincy; 2015.

15.

Tulacz GJ. The Top 100 green contractors. Tech. Rep. September, Engineering News-Record; 2012.

16.

IBCC-12. International building code and commentary volume 1; 2011.

17.

IBCC-12. International building code and commentary volume 2; 2011.

18.

IFCC-12. International fire code and commentary; 2011.

19.

NFPA 1. Fire code; 2014.

20.

Universitè de Liège. Functionalities of the software SAFIR; 2005.

21.

McGrattan K, Hostikka S, McDermott R, Floyd J, Weinschenk C, Overholt K. Fire dynamics simulator users guide. Tech. Rep. National Institute of Standards and Technology; 2015.

22.

Forney GP. Smokeview, a tool for visualizing fire dynamics simulation data volume I: users guide. Tech. Rep. 1017-1, National Institute of Standards and Technology; 2015.

23.

Korhonen T. Fire dynamics simulator with evacuation: FDS+Evac technical reference and users guide. Tech. Rep., VTT Technical Research Centre of Finland; 2015.

24.

Gollner M, Kimball A, Vecchiarelli T. Fire safety design and sustainable buildings: challenges and opportunities report of a national symposium. In: Fire safety design and sustainable buildings: challenges and opportunities. NFPA; 2012.

25.

EPA. Components of green building. July 2003. http://archive.epa.gov/greenbuilding/web/html/components.html. Accessed 12 Sept 2015.

26.

WBDG Sustainable Committee. Sustainable—whole building design guide. 2014. http://www.wbdg.org/design/sustainable.php. Accessed 12 Sept 2015.

27.

U.S. Green Building Council. Green building facts. 2015. http://www.usgbc.org/articles/green-building-facts. Accessed 12 Sept 2015.

28.

EPA. US Green Building Council’s Leadership in Energy and Environmental Design (LEED). 2015. http://www2.epa.gov/smartgrowth/us-green-building-councils-leadership-energy-and-environmental-design-leedr. Accessed 12 Sept 2015.

29.

EPA. Basic information—green building. 2014. http://archive.epa.gov/greenbuilding/web/html/about.html. Accessed 12 Sept 2015.

30.

ICC 700-2012. National Green Building Standard. NAHB; 2013.

31.

National Association of Home Builders. ICC 700 National Green Building Standard. 2015. https://www.nahb.org/en/research/nahb-priorities/green-building-remodeling-and-development/ngbs-green-certification.aspx. Accessed 12 Sept 2015.

32.

EPA. ICC 700-2012: 2012 National Green Building Standard (ICC 700). 2015. http://www2.epa.gov/smartgrowth/icc-700-2012-2012-national-green-building-standard-icc-700. Accessed 12 Sept 2015.

33.

EPD International AB. What is an EPD—Environmental Product Declarations. 2014. http://environdec.com/en/What-is-an-EPD/#.VfSGQflVikp. Accessed 12 Sept 2015.

34.

ISO 14040:2006. Environmental management—life cycle assessment—principles and framework. 2006.

35.

ISO 14044:2006. Environmental management—life cycle assessment—requirements and guidelines. 2006.

36.

Barista D. Manufacturers race to offer EPDs, HPDs in response to LEED v4. 2014. http://www.bdcnetwork.com/blog/manufacturers-race-offer-epds-hpds-response-leed-v4. Accessed 12 Sept 2015.

37.

ASTM E2921-13. Standard practice for minimum criteria for comparing whole building life cycle assessments for use with building codes and rating systems; 2013.

38.

Athena Sustainable Materials Institute. IE for buildings. 2015. http://www.athenasmi.org/our-software-data/impact-estimator/. Accessed 12 Sept 2015.

39.

Greig AL, Kneifel J. BEES please questionnaire: users guide. Tech. Rep., NIST; 2014.

40.

NREL. U.S. Life Cycle Inventory Database. 2015. http://www.nrel.gov/lci/. Accessed 12 Sept 2015.

41.

GreenDelta. openLCA. 2014. http://www.openlca.org/openlca. Accessed 12 Sept 2015.

42.

Carnegie Mellon University. Economic input–output life cycle assessment. 2015. http://www.eiolca.net/index.html. Accessed 12 Sept 2015.

43.

CEDA. The origins of CEDA. 2011. http://cedainformation.net/CEDA_origins.html. Accessed 12 Sept 2015.

44.

2012 IgCC. International Green Construction Code; 2012.

45.

ANSI/ASHRAE/USGBC/IES Standard 189.1-2014. Standard for the design of high-performance green buildings. ASHRAE and U.S. Green Building Council; 2014.

46.

EPA. International Code Council’s 2012 International Green Construction Code (IgCC). 2015. http://www2.epa.gov/smartgrowth/international-code-councils-2012-international-green-construction-code-igcc. Accessed 12 Sept 2015.

47.

Busta H. Industry groups to evolve the International Green Construction Code. Architect; 2014.

48.

Tidwell J, Murphy JJ. Bridging the gap: fire safety and green buildings. Tech. Rep., National Association of State Fire Marshals; 2010.

49.

Spadafora R. Sustainable green design and firefighting: a fire chief’s perspective. Go Green with Renewable Energy Resources Series, Cengage Learning; 2012.

50.

NFPA. Quantification of green building features on firefighter safety. Tech. Rep., The Fire Protection Research Foundation; 2013.

51.

Marlair G, Simonson M, Gann RG. Environmental concerns of fires: facts, figures, questions and new challenges for the future. In: Interflam. Interscience Communications Ltd.; 2004. p. 325–37.

52.

ISO 26367-1:2011. Guidelines for assessing the adverse environmental impact of fire effluents—part 1: general; 2011.

53.

Robbins A. Building sustainability and fire-safety design interactions: scoping study. Tech. Rep., BRANZ; 2012.

54.

Andersson P, Simonson M, Tullin C, Stripple H, Sundqvist JO, Paloposki T. Fire-LCA guidelines. Tech. Rep., SP Swedish National Testing and Research Institute; 2004.

55.

Simonson M, Andersson P, Blomqvist P, Stripple HK. Environmental assessment of fires in products using the Fire-LCA model. Fire Safety Science; 2005. p. 1071–82.

56.

Andersson P, Simonson M, Rosell L, Blomqvist P, Stripple H. Fire-LCA model: cable case study II—NHXMH and NHMH cable. Tech. Rep.; 2005.

57.

Hamzi R, Londiche H, Bourmada N. Fire-LCA model for environmental decision-making. Chem Eng Res Des. 2008;86(10):1161–6.CrossRef

58.

Chettouh S, Hamzi R, Innal F, Haddad D. Uncertainty in the dynamic LCA—fire methodology to assess the environmental fire effects. In: Proceedings of the 3rd International Conference on Systems and Control, IEEE; 2013.

59.

Andersson P, Simonson M, Stripple HK. Fire safety of upholstered furniture, a life-cycle assessment summary report. Tech. Rep., SP Swedish National Testing and Research Institute, 2003.

60.

Duval R. Perfect storm. NFPA Journal; 2014.

61.

Organic Valley Family of Farms. Organic Valley—history. http://www.organicvalley.coop/about-us/overview/our-history/. Accessed 12 Sept 2015.

62.

Backstrom R, Dini D. Firefighter safety and photovoltaic installations research project. Tech. Rep., Underwriters Laboratories Inc., Northbrook; 2011.

63.

Izydorek MS, Zeeveld PA, Samuels MD, Smyser JP, Berhinig RM. Report on structural stability of engineered lumber in fire conditions. Tech. Rep., Underwriters Laboratories Inc., Northbrook; 2008.

64.

ASTM E84-13a. Standard test method for surface burning characteristics of building materials; 2013.

65.

UL 723. Standard for test for surface burning characteristics; 2008.

66.

Utiskul Y, Wu NP. Residential fire sprinklers water usage and water meter performance study. Tech. Rep., The Fire Protection Research Foundation; 2011.

67.

NFPA 13. Standard for the installation of sprinkler systems; 2013.

68.

EPA. Greening EPA glossary. 2013. http://www.epa.gov/greeningepa/glossary.htm. Accessed 12 Sept 2015.

69.

Bushby ST. Integrating fire alarm systems with building automation and control systems. Fire Protection Engineering; 2001.

70.

Maehlum MA. Micro-inverters vs. central inverters; 2014. http://energyinformative.org/are-solar-micro-inverters-better-than-central-inverters/. Accessed 12 Feb 2015.

71.

ASTM E108-11. Standard test methods for fire tests of roof coverings; 2011.

72.

UL 1703. Standard for safety flat-plate photovoltaic modules and panels; 2015.

73.

Brooks Engineering. Fire ratings of PV systems: a guide for stakeholders. Tech. Rep., NREL; 2014.

74.

ASTM E119-12a. Standard test methods for fire tests of building construction and materials; 2012.

75.

Murphy JJ, Tidwell J. Green building challenges for the fire service. Fire Engineering, no. January; 2011. p. 41–55.

76.

UL 1741. Standard for safety inverters, converters, controllers and interconnection system equipment for use with distributed energy resources; 2010.

77.

Brooks B. The ground-fault protection blind spot: a safety concern for larger photovoltaic systems in the United States. Tech. Rep., Solar America Board for Codes and Standards; 2012.

78.

Brooks W. Field guide for testing existing photovoltaic systems for ground faults and installing equipment to mitigate fire hazards. Tech. Rep., NREL; 2015.

79.

Navigant Consulting Inc. Community, residential, and commercial energy storage. Tech. Rep., Navigant Consulting, Inc.; 2014.

80.

U.S. Environmental Protection Agency. Recommended levels of insulation: energy star; 2015. https://www.energystar.gov/index.cfm?c=home_sealing.hm_improvement_insulation_table. Accessed 10 Jan 2015.

81.

Mehaffey J. Fire performance of combustible insulation in buildings. J Build Phys. 1987;10:256–69.CrossRef

82.

Zicherman J. Fire performance of foam-plastic building insulation. J Archit Eng. 2003;9:97–101.CrossRef

83.

Ahrens M. Home structure fires. Tech. Rep., National Fire Protection Association: Quincy; 2013.

84.

Roberts B, Webber M, Ezekoye O. Development of a multi-objective optimization tool for selecting thermal insulation materials in sustainable designs. Energy Build. 2015;105:358–67.CrossRef

Titel: Why and How the Sustainable Building Community Should Embrace Fire Safety
verfasst von: Bonnie C. Roberts
Michael E. Webber
Ofodike A. Ezekoye
Publikationsdatum: 01.12.2016
Verlag: Springer International Publishing
Erschienen in: Current Sustainable/Renewable Energy Reports / Ausgabe 3-4/2016
Elektronische ISSN: 2196-3010
DOI: https://doi.org/10.1007/s40518-016-0060-2

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