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The building energy performance gap in multifamily buildings : a detailed case study analysis of the energy demand and collective heating system

Stijn Van de Putte (UGent) , Marijke Steeman (UGent) and Arnold Janssens (UGent)
(2025) SUSTAINABILITY. 17(1).
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Abstract
The building energy performance gap, resulting from a discrepancy between the actual energy use and theoretical calculations, remains a persistent issue in building design. This study examines the energy performance of three multifamily buildings with a collective heating system powered by gas boilers and solar collectors: two that underwent deep renovation and one newly built. An extensive on-site monitoring system provides detailed data on both the heating demand and the final energy use. To ensure comparability, the total energy use of each unit is normalised using the energy signature method. The findings show the large spread of actual energy demands due to a wide variation in user profiles. The majority of dwellings have an actual energy use that is significantly higher than calculated, which is largely attributable to space heating. The gap is further exacerbated by substantial heat losses within the building's heating system and by limited gains from the solar collectors, indicating discrepancies between design models and operational realities. To bridge this gap, there is a need for rigorous commissioning processes, at least during the initial operation phase start-up and ideally continuously. This can ensure more effective utilisation of renewable energy sources and reduce energy inefficiencies.
Keywords
multifamily building, energy-efficient building, collective heating system, renewable energy, solar thermal collectors, energy performance gap, system efficiency, actual energy use, energy renovation, energy savings, CONSUMPTION, BEHAVIOR, TEMPERATURES, METHODOLOGY, RETROFITS, DWELLINGS, WELL

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MLA
Van de Putte, Stijn, et al. “The Building Energy Performance Gap in Multifamily Buildings : A Detailed Case Study Analysis of the Energy Demand and Collective Heating System.” SUSTAINABILITY, vol. 17, no. 1, 2025, doi:10.3390/su17010252.
APA
Van de Putte, S., Steeman, M., & Janssens, A. (2025). The building energy performance gap in multifamily buildings : a detailed case study analysis of the energy demand and collective heating system. SUSTAINABILITY, 17(1). https://doi.org/10.3390/su17010252
Chicago author-date
Van de Putte, Stijn, Marijke Steeman, and Arnold Janssens. 2025. “The Building Energy Performance Gap in Multifamily Buildings : A Detailed Case Study Analysis of the Energy Demand and Collective Heating System.” SUSTAINABILITY 17 (1). https://doi.org/10.3390/su17010252.
Chicago author-date (all authors)
Van de Putte, Stijn, Marijke Steeman, and Arnold Janssens. 2025. “The Building Energy Performance Gap in Multifamily Buildings : A Detailed Case Study Analysis of the Energy Demand and Collective Heating System.” SUSTAINABILITY 17 (1). doi:10.3390/su17010252.
Vancouver
1.
Van de Putte S, Steeman M, Janssens A. The building energy performance gap in multifamily buildings : a detailed case study analysis of the energy demand and collective heating system. SUSTAINABILITY. 2025;17(1).
IEEE
[1]
S. Van de Putte, M. Steeman, and A. Janssens, “The building energy performance gap in multifamily buildings : a detailed case study analysis of the energy demand and collective heating system,” SUSTAINABILITY, vol. 17, no. 1, 2025.
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  abstract     = {{The building energy performance gap, resulting from a discrepancy between the actual energy use and theoretical calculations, remains a persistent issue in building design. This study examines the energy performance of three multifamily buildings with a collective heating system powered by gas boilers and solar collectors: two that underwent deep renovation and one newly built. An extensive on-site monitoring system provides detailed data on both the heating demand and the final energy use. To ensure comparability, the total energy use of each unit is normalised using the energy signature method. The findings show the large spread of actual energy demands due to a wide variation in user profiles. The majority of dwellings have an actual energy use that is significantly higher than calculated, which is largely attributable to space heating. The gap is further exacerbated by substantial heat losses within the building's heating system and by limited gains from the solar collectors, indicating discrepancies between design models and operational realities. To bridge this gap, there is a need for rigorous commissioning processes, at least during the initial operation phase start-up and ideally continuously. This can ensure more effective utilisation of renewable energy sources and reduce energy inefficiencies.}},
  articleno    = {{252}},
  author       = {{Van de Putte, Stijn and Steeman, Marijke and Janssens, Arnold}},
  issn         = {{2071-1050}},
  journal      = {{SUSTAINABILITY}},
  keywords     = {{multifamily building,energy-efficient building,collective heating system,renewable energy,solar thermal collectors,energy performance gap,system efficiency,actual energy use,energy renovation,energy savings,CONSUMPTION,BEHAVIOR,TEMPERATURES,METHODOLOGY,RETROFITS,DWELLINGS,WELL}},
  language     = {{eng}},
  number       = {{1}},
  pages        = {{37}},
  title        = {{The building energy performance gap in multifamily buildings : a detailed case study analysis of the energy demand and collective heating system}},
  url          = {{http://doi.org/10.3390/su17010252}},
  volume       = {{17}},
  year         = {{2025}},
}
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