Thermally anisotropic building envelope for thermal management: finite element model calibration using field evaluation data

Daniel Howard, Som S. Shrestha, Zhenglai Shen, Tianli Feng, Diana Hun

Research output: Contribution to journalArticlepeer-review

1 Scopus citations

Abstract

The thermally anisotropic building envelope (TABE) is an active building envelope that redistributes thermal loads in response to weather conditions and building energy demand. Conductive layers throughout the TABE distribute low-grade heat among hydronic loops, altering heat flow direction and intensity. Finite element models of TABE roof and wall panels were developed and calibrated using field evaluation data. The calibration results showed that heat flux differences between the experimental data and finite element models averaged −0.42% and 3.57%, with a maximum mean square error of 1.78 and 3.96 for roof and wall panels, respectively. A reduction in heat flux from the environment to the building living space over the entire testing period (weeks in July/August) was found to be 85% for roof panels and 335% (load reversed) for wall panels. These results indicate TABE can effectively harness low-grade thermal energy sources to achieve high energy efficiency and promote demand-side management.

Original languageEnglish
JournalJournal of Building Performance Simulation
DOIs
StateAccepted/In press - 2024

Keywords

  • active building envelope
  • energy efficiency
  • finite element model calibration
  • thermal management
  • Thermally anisotropic building envelope

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