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A review of HVAC solution-sets and energy performace of nearly zero-energy multi-story apartment buildings in Nordic climates by statistical analysis of environmental performance certificates and literature review

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  • Gibbons, Laurence
  • Javed, Saqib

Abstract

Multi-story apartment buildings, also known as multi-family or multi-unit residential buildings, represent the largest share of newly constructed, residential floor area in Norway, Sweden and Finland. Since the start of 2021, these buildings are required to be nearly-zero-energy under the Energy Performance of Buildings Directive. However, there has been limited research into defining solution-sets to achieve these requirements. This study utilises the detailed databases of Energy Performance Certificates (EPCs) of the three countries to analyse solutions used in low-energy buildings built in the last 20 years. This was supplemented by exemplar projects and literature presenting novel solutions. Resulting low-energy solution-sets involved district heating or heat pumps (primarily ground source) to provide hydronic heating and domestic hot water. A secondary source (often direct electric) was commonly used to cover peak load. The dominant ventilation strategy was balanced ventilation with high efficiency heat recovery. An alternative, found in a minority of Swedish projects, was an exhaust air system integrating a heat pump. A single optimum solution-set could not be defined due to differences between regulations and climates. The different primary energy factors used in each country had a significant effect on the preferred solution. Further study is required to determine if these factors affect a country's entire building stock or just the EPC grade a building achieves, skewing the statistical results.

Suggested Citation

  • Gibbons, Laurence & Javed, Saqib, 2022. "A review of HVAC solution-sets and energy performace of nearly zero-energy multi-story apartment buildings in Nordic climates by statistical analysis of environmental performance certificates and lite," Energy, Elsevier, vol. 238(PA).
    • Handle: RePEc:eee:energy:v:238:y:2022:i:pa:s0360544221019575
    DOI: 10.1016/j.energy.2021.121709
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    3. Andrea Ferrantelli & Jarek Kurnitski, 2022. "Energy Performance Certificate Classes Rating Methods Tested with Data: How Does the Application of Minimum Energy Performance Standards to Worst-Performing Buildings Affect Renovation Rates, Costs, E," Energies, MDPI, vol. 15(20), pages 1-19, October.

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