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Life cycle primary energy implication of retrofitting a wood-framed apartment building to passive house standard

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  • Dodoo, Ambrose
  • Gustavsson, Leif
  • Sathre, Roger

Abstract

Here we analyze the life cycle primary energy implication of retrofitting a four-storey wood-frame apartment building to the energy use of a passive house. The initial building has an annual final energy use of 110kWh/m2 for space and tap water heating. We model improved thermal envelope insulation, ventilation heat recovery, and efficient hot water taps. We follow the building life cycle to analyze the primary energy reduction achieved by the retrofitting, considering different energy supply systems. Significantly greater life cycle primary energy reduction is achieved when an electric resistance heated building is retrofitted than when a district heated building is retrofitted. The primary energy use for material production increases when the operating energy is reduced but this increase is more than offset by greater primary energy reduction during the operation phase of the building, resulting in significant life cycle primary energy savings. Still, the type of heat supply system has greater impact on primary energy use than the final heat reduction measures.

Suggested Citation

  • Dodoo, Ambrose & Gustavsson, Leif & Sathre, Roger, 2010. "Life cycle primary energy implication of retrofitting a wood-framed apartment building to passive house standard," Resources, Conservation & Recycling, Elsevier, vol. 54(12), pages 1152-1160.
    • Handle: RePEc:eee:recore:v:54:y:2010:i:12:p:1152-1160
    DOI: 10.1016/j.resconrec.2010.03.010
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    References listed on IDEAS

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    1. Gustavsson, Leif & Karlsson, Asa, 2002. "A system perspective on the heating of detached houses," Energy Policy, Elsevier, vol. 30(7), pages 553-574, June.
    2. Sathre, Roger & Gustavsson, Leif, 2006. "Energy and carbon balances of wood cascade chains," Resources, Conservation & Recycling, Elsevier, vol. 47(4), pages 332-355.
    3. Leif Gustavsson & Åsa Karlsson, 2006. "CO 2 Mitigation: On Methods and Parameters for Comparison of Fossil-Fuel and Biofuel Systems," Mitigation and Adaptation Strategies for Global Change, Springer, vol. 11(5), pages 935-959, September.
    4. Schnieders, Jurgen & Hermelink, Andreas, 2006. "CEPHEUS results: measurements and occupants' satisfaction provide evidence for Passive Houses being an option for sustainable building," Energy Policy, Elsevier, vol. 34(2), pages 151-171, January.
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    Cited by:

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    2. Kylili, Angeliki & Ilic, Milos & Fokaides, Paris A., 2017. "Whole-building Life Cycle Assessment (LCA) of a passive house of the sub-tropical climatic zone," Resources, Conservation & Recycling, Elsevier, vol. 116(C), pages 169-177.
    3. Vefago, Luiz H. Maccarini & Avellaneda, Jaume, 2013. "Recycling concepts and the index of recyclability for building materials," Resources, Conservation & Recycling, Elsevier, vol. 72(C), pages 127-135.
    4. Syed Shujaa Safdar Gardezi & Nasir Shafiq & Muhammad Waris Ali Khan, 2022. "Relational pre-impact assessment of conventional housing features and carbon footprint for achieving sustainable built environment," Environment, Development and Sustainability: A Multidisciplinary Approach to the Theory and Practice of Sustainable Development, Springer, vol. 24(6), pages 8441-8463, June.

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