대한건축학회논문집:구조계 (Journal of the Architectural Institute of Korea Structure & Construction)

대한건축학회 (Architectural Institute of Korea)
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재실자 쾌적을 고려한 창호 설계 관점에서의 건물에너지 효율화 정책 개선방안

A Study on Building Energy Efficiency Policies Improvement Considering Window Design for Occupants Comfort

  • 오지현 (아주대학교 대학원 건축학과) ;
  • 김선숙 (아주대학교 건축학과)
  • 투고 : 2016.09.19
  • 심사 : 2016.11.18
  • 발행 : 2016.11.30
⟨ 이전 논문 다음 논문 ⟩

초록

In a way of encouraging energy efficient and sustainable buildings, many countries provide regulations and informations on building envelope design in various levels including codes and standards, building certification systems and design guidelines. Recently, the Korea government developed and improved several codes and guidelines on window design, but they are practically concentrated on energy performance. Although window has a complicated impact on building energy use and occupants comfort, thermal and visual comfort has not concerned sufficiently with multiple design factors. The purpose of this paper is to suggest some considerations and strategies to improve of domestic standard and guideline in terms of window design for occupants comfort. Codes and standards, certification systems, and guidelines in foreign countries were investigated and analyzed. Based on this result, we suggested some considerations to improve the daylighting and ventilation criteria influencing on window design for thermal/visual comfort in Korean Building Energy Conservation Code(BECC).

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과제정보

연구 과제 주관 기관 : 한국연구재단

참고문헌

  1. ABCB. (2015). National Construction Code Series Vol.1 -Building Code of Australia Class 2 to Class 9 Buildings. Canberra: Australian Building Codes Board, Australia Building Code Board.
  2. ABCB. (2015). National Construction Code Series Vol.2 -Building Code of Australia Class 1 and Class 10 Buildings. Canberra: Australian Building Codes Board, Board, Australia Building Code Board.
  3. AGDI. (2013). Your Home, 5th Edition, Canberra: Australian Government by the Department of Industry.
  4. ASHRAE. (2013). ANSI/ASHRAE/IES Standard 90.1 -2013, Energy Standard for Buildings Except Low-Rise Residential Buildings. Atlanta: American Society of Heating, Refrigerating and Air Conditioning Engineers
  5. ASHRAE. (2010). Thermal Environmental Conditions for Human Occupancy, Atlanta: American Society of Heating, Refrigerating and Air Conditioning Engineers, Inc.
  6. ASHRAE. (2016). Ventilation for Acceptable Indoor Air Quality, Atlanta: American Society of Heating, Refrigerating and Air Conditioning Engineers, Inc.
  7. BCA. (1986). Hancbook on Energy Conservation in Buildings and Building Services, Singapore: Building and Construction Authority, Singapore: Building and Construction Authority.
  8. BCA. (2012). 2013 The Code for Environmental Sustainability of buildings, 3rd Edition, Singapore: Building and Construction Authority.
  9. bigEE. (2013). How policies need to interact in packages
  10. BRE. (2014). BREEAM UK New Construction, London: Building Research Establishment.
  11. CIBSE. (2015). CIBSE Guide A: Environmental Design 8th Edition, London: The Chartered Institution of Building Services Engineers.
  12. CIBSE. (2015). CIBSE Applications Manual 10: Natural Ventilation in Non-Domestic Buildings, London: The Chartered Institution of Building Services Engineers.
  13. DBEDT. (2004). Hawaii Commercial Building Guidelines for Energy Efficiency, Honolulu: Depart of Business, Economic Development and Tourism, State of Hawaii.
  14. DCLG. (2014). The Building Regulation 2010 Approved Document Part L1A - Conservation of Fuel and Power in New Dwellings. London: Department of Communities and Local Government.
  15. DCLG. (2014). The Building Regulation 2010 Approved Document Part L2A - Conservation of Fuel and Power in New Buildings other than Dwellings. London: Department for Communities and Local Government.
  16. DOE. (2014). Windows and Building Envelope Research and Development: Roadmap for Emeerging technologies, Washington D.C: The U.S Department of Energy.
  17. IBE. (2012). Driving Transformation to Energy Efficient Buildings: Policies and Actions 2nd Edition, Milwaukee: Insititute for Building Efficincy, Johnson Controls Inc.
  18. ICC. (2014). 2015 International Energy Conservation Code. Washington D.C.: International Code Council
  19. Kim, S. (2015). Improvement of window and shading criteria for reducing solar gain by analysis of korea and foreign building code. Journal of KIAEBS, Vol.9 No.5, 2015-10
  20. Kim, S. (2009). An analysis of the component and development characteristics of green building guidelines. Journal of The Architectural Institute of Korea, v.25 n.05
  21. MOLIT. (2015). The Building Energy Conservation Code, Sejong: Ministry of Land, Infrastructure and Transport.
  22. MOLIT. (2015). The Sustainable Housing Construction Code for Energy Savings. 2015-994, Sejong: Ministry of Land, Infrastructure and Transport.
  23. MOLIT. (2016). The Green Building Certification System Code, 2016-341, Sejong: Ministry of Land, Infrastructure and Transport.
  24. MOLIT. (2012). The Window Design Guidelines for Building Energy Conservation, Sejong: Ministry of Land, Infrastructure and Transport.
  25. NEA. (2005). The Energy Smart Label-Office, Singapore: The National Environment Agency.
  26. Oh, J., Sung, J. & Kim, S. (2016). Standard and Guideline Improvement Considering Building Envelope Design for Occupants Comfort, The Architectural Institute of Korea Spring Conference, Vol.36 No.1 (2016-04)
  27. PCAP. (2012). Passive Design Guideline, Seoul: Presidential Commission on Architecture Policy.
  28. USGBC. (2013). Leadership in Energy and Environmental Design ver.4, Washington D.C: The U.S Green Building Conucil.
  29. http://www.gbca.org.au/