Influence of envelope insulation materials on building energy consumption
Received date: 17 Feb 2017
Accepted date: 20 Apr 2017
Published date: 14 Dec 2017
Copyright
In this paper, the influence of different external wall insulation materials on the energy consumption of a newly built apartment in Germany is investigated. Three types of insulation materials commonly used in Germany including mineral fiber, polyurethane, and vacuum insulation panel are chosen for the case studies. An energy analysis model is established to clarify the primary energy use for production of the insulation materials and for building space heating. The calculation results show that the energy consumption for insulation material production increases with the insulation thickness, whereas the energy use for space heating decreases with the insulation thickness. Thus, there exists an optimum thickness to get the lowest total energy consumption for each kind of insulation material. The ascending order of the total energy consumption of the three materials is mineral fiber, polyurethane, and vacuum insulation panel. However, the optimum insulation thicknesses for the three insulation materials show a verse order at a certain heat transfer coefficient of the base envelope. The energy payback time (EPT) is proposed to calculate the payback time of the primary energy use for insulation material production. Mineral fiber has the shortest time, followed by polyurethane and vacuum insulation panel. The EPTS is 10, 19 and 21 years, respectively when the heat transfer coefficient of the base envelope is 0.2 W/(m2·K). In addition, the simulated results show that the theoretical value and the simulated value are basically identical.
Key words: building envelope; insulation materials; energy consumption; payback time
Junlan YANG , Jiabao TANG . Influence of envelope insulation materials on building energy consumption[J]. Frontiers in Energy, 2017 , 11(4) : 575 -581 . DOI: 10.1007/s11708-017-0473-7
| 1 |
Khasreen M M, Banfill P F G, Menzies G F. BanfillPhillip F G, Menzies G F. Life-cycle assessment and the environmental impact of buildings: a review. Sustainability, 2009, 1(3): 674–701
|
| 2 |
Klöpffer W. Therole of SETAC in the development of LCA.International Journal of Life Cycle Assessment, 2006, 11(S1): 116–122
|
| 3 |
Gu D, Zhu Y, Gu L. Life cycle assessment for China building environment impacts. Journal of Tsinghua University (Science & Technology), 2006, 46(12): 1953–1956
|
| 4 |
Robin D, Michael A, Selwyn T. Automating building life cycle energy assessment. In: International Council for Research and Innovation in Building and Construction CIB w78 Conference. Aarhus School of Architecture, Denmark, 2002, 1–8
|
| 5 |
Carol M. LCA of innovative high energy performance envelope. 2007
|
| 6 |
Fay R, Treloar G, Iyerraniga U. Life-cycle energy analysis of buildings: a case study. Building Research and Information, 2000, 28(1): 31–41
|
| 7 |
Gu D J, Gu L J, Zhu Y X. A life cycle assessment method for buildings. In: Proceedings of Building Simulation. Beijing, China, 2007, 1595–1600
|
| 8 |
Shi J F, Li A G, Chen S L. Research on the thickness of economical insulation layer of external wall in Xi’an.Architecture Technology & Design, 2008, 9(9):78–83
|
| 9 |
Zhang X. Assessment method of building energy consumption based on LCA. Refrigeration Air Conditioning & Electric Power Machinery, 2002, 23(4):1–3
|
| 10 |
Zheng G Z, Jing Y Y, Huang H X, Gao Y F. Application of life cycle assessment (LCA) and extenics theory for building energy conservation assessment. Energy, 2009, 34(11): 1870–1879
|
| 11 |
Tarantini M, Loprieno A D, Porta P L. A life cycle approach to green public procurement of building materials and elements: a case study on windows. Energy, 2011, 36(5): 2473–2482
|
| 12 |
Malmqvist T, Glaumann M, Scarpellini S, Zabalza I, Aranda A, Llera E, Díaz S. Life cycle assessment in buildings: the ENSLIC simplified method and guidelines. Energy, 2011, 36(4): 1900–1907
|
| 13 |
Tsai W H, Lin S J, Liu J Y, Lin W R, Lee K C. Incorporating life cycle assessments into building project decision-making: an energy consumption and CO2 emission perspective. Energy, 2011, 36(5): 3022–3029
|
| 14 |
Zabalza I, Aranda A, Scarpellini S, Díaz S. Life cycle assessment in building sector: state of the art and assessment of environmental impact for building materials. In: The 1st International Exergy, Life Cycle Assessment, and Sustainability Workshop & Symposium (ELCAS) 2009. Nisyros, Greece, 2009
|
| 15 |
Huberman N, Pearlmutter D. A life-cycle energy analysis of building materials in the Negev desert. Energy and Building, 2008, 40(5): 837–848
|
| 16 |
Ardente F, Beccali M, Cellura M, Mistretta M. Building energy performance: a LCA case study of kenaf-fibres insulation board. Energy and Building, 2008, 40(1): 1–10
|
| 17 |
Blengini G A, Di Carlo T. The changing role of life cycle phases, subsystems and materials in the LCA of low energy buildings. Energy and Building, 2010, 42(6): 869–880
|
| 18 |
Ramesh T, Prakash R, Shukla K K. Life cycle energy analysis of buildings: an overview. Energy and Building, 2010, 42(10): 1592–1600
|
| 19 |
ISO 14040. Environmental management life cycle assessment principles and framework.In: International Standards Organization. Brussels, Belgium, 2006
|
| 20 |
Siraki K.Life cycle assessment of residential buildings.Dissertation for Doctoral Degree. Bochum: Ruhr-University Bochum, 2007, 3
|
/
| 〈 |
|
〉 |