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Energy storage and heat extraction – From thermally activated building systems (TABS) to thermally homeostatic buildings

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  • Ma, Peizheng
  • Wang, Lin-Shu
  • Guo, Nianhua

Abstract

The trend toward high envelope R-value for building energy efficiency made sense because at the starting point when the trend began in 1980s and 1990s buildings were poorly insulated. The advantage of high performance envelope was based on the consideration of envelope heat transfer and building heat balance (balance between heat transfer loss and fuel heat production). However, high performance envelope is not the silver bullet to building energy efficiency. A more comprehensive consideration of building energy efficiency should take into account of energy storage and heat extraction. In this paper we present a review of engineering literature on these two related topics: energy storage with special focus on thermally activated building systems (TABS) as the example of energy storage; heat extraction with the idea of homeostasis providing the context in the application of heat extraction. TABS combines the advantage of radiant surface heating and cooling and the utilization of building structure as thermal energy storage. This proved to be a critical step. This critical review argues that the hydronic circuit for radiant surface cooling offers the necessary element for extracting heat from indoor, thus, makes it possible for combining radiant conditioning, energy storage, and general practice of heat extraction—the resulting synergy of which will be called homeostasis in buildings.

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  • Ma, Peizheng & Wang, Lin-Shu & Guo, Nianhua, 2015. "Energy storage and heat extraction – From thermally activated building systems (TABS) to thermally homeostatic buildings," Renewable and Sustainable Energy Reviews, Elsevier, vol. 45(C), pages 677-685.
  • Handle: RePEc:eee:rensus:v:45:y:2015:i:c:p:677-685
    DOI: 10.1016/j.rser.2015.02.017
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    References listed on IDEAS

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    1. Ma, Peizheng & Wang, Lin-Shu & Guo, Nianhua, 2014. "Modeling of hydronic radiant cooling of a thermally homeostatic building using a parametric cooling tower," Applied Energy, Elsevier, vol. 127(C), pages 172-181.
    2. Ma, Peizheng & Wang, Lin-Shu & Guo, Nianhua, 2015. "Maximum window-to-wall ratio of a thermally autonomous building as a function of envelope U-value and ambient temperature amplitude," Applied Energy, Elsevier, vol. 146(C), pages 84-91.
    3. Kalz, Doreen E. & Pfafferott, Jens & Herkel, Sebastian & Wagner, Andreas, 2011. "Energy and efficiency analysis of environmental heat sources and sinks: In-use performance," Renewable Energy, Elsevier, vol. 36(3), pages 916-929.
    4. Ma, Peizheng & Wang, Lin-Shu & Guo, Nianhua, 2013. "Modeling of TABS-based thermally manageable buildings in Simulink," Applied Energy, Elsevier, vol. 104(C), pages 791-800.
    5. Lehmann, B. & Dorer, V. & Gwerder, M. & Renggli, F. & Tödtli, J., 2011. "Thermally activated building systems (TABS): Energy efficiency as a function of control strategy, hydronic circuit topology and (cold) generation system," Applied Energy, Elsevier, vol. 88(1), pages 180-191, January.
    6. Gwerder, M. & Tödtli, J. & Lehmann, B. & Dorer, V. & Güntensperger, W. & Renggli, F., 2009. "Control of thermally activated building systems (TABS) in intermittent operation with pulse width modulation," Applied Energy, Elsevier, vol. 86(9), pages 1606-1616, September.
    7. Kalz, Doreen E. & Wienold, Jan & Fischer, Martin & Cali, Davide, 2010. "Novel heating and cooling concept employing rainwater cisterns and thermo-active building systems for a residential building," Applied Energy, Elsevier, vol. 87(2), pages 650-660, February.
    8. Gwerder, M. & Lehmann, B. & Tödtli, J. & Dorer, V. & Renggli, F., 2008. "Control of thermally-activated building systems (TABS)," Applied Energy, Elsevier, vol. 85(7), pages 565-581, July.
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    Cited by:

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    3. María M. Villar-Ramos & Iván Hernández-Pérez & Karla M. Aguilar-Castro & Ivett Zavala-Guillén & Edgar V. Macias-Melo & Irving Hernández-López & Juan Serrano-Arellano, 2022. "A Review of Thermally Activated Building Systems (TABS) as an Alternative for Improving the Indoor Environment of Buildings," Energies, MDPI, vol. 15(17), pages 1-31, August.
    4. Pallonetto, Fabiano & De Rosa, Mattia & D’Ettorre, Francesco & Finn, Donal P., 2020. "On the assessment and control optimisation of demand response programs in residential buildings," Renewable and Sustainable Energy Reviews, Elsevier, vol. 127(C).
    5. Valentina Bonetti & Georgios Kokogiannakis, 2017. "Dynamic Exergy Analysis for the Thermal Storage Optimization of the Building Envelope," Energies, MDPI, vol. 10(1), pages 1-19, January.
    6. Wang, Lin-Shu & Ma, Peizheng, 2016. "The homeostasis solution – Mechanical homeostasis in architecturally homeostatic buildings," Applied Energy, Elsevier, vol. 162(C), pages 183-196.
    7. Yang, Yang & Chen, Sarula, 2022. "Thermal insulation solutions for opaque envelope of low-energy buildings: A systematic review of methods and applications," Renewable and Sustainable Energy Reviews, Elsevier, vol. 167(C).
    8. Hawks, M.A. & Cho, S., 2024. "Review and analysis of current solutions and trends for zero energy building (ZEB) thermal systems," Renewable and Sustainable Energy Reviews, Elsevier, vol. 189(PB).
    9. Lizana, Jesús & Chacartegui, Ricardo & Barrios-Padura, Angela & Ortiz, Carlos, 2018. "Advanced low-carbon energy measures based on thermal energy storage in buildings: A review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 82(P3), pages 3705-3749.
    10. Wu, Wentao & Zhang, Wei & Benner, Jingru & Malkawi, Ali, 2020. "Critical evaluation of analytical methods for thermally activated building systems," Renewable and Sustainable Energy Reviews, Elsevier, vol. 117(C).

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