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Building Simulation

, Volume 11, Issue 3, pp 519–531 | Cite as

Hysteresis effects on the thermal performance of building envelope PCM-walls

  • Efraín Moreles
  • Guadalupe Huelsz
  • Guillermo Barrios
Research Article Building Thermal, Lighting, and Acoustics Modeling

Abstract

This work presents a numerical study of the combined effects of the hysteresis temperature difference, peak melting temperature, and thickness of a building envelope PCM-wall on its thermal performance in air-conditioning and non-air-conditioning conditions. The study was carried out considering complete melting-freezing daily cycles of the PCM in a climate exhibiting both hot and cold thermal discomfort. A time-dependent one-dimensional heat conduction code, which uses the effective specific heat method to simulate the heat transfer through the PCM was developed. Insights into the effects of the hysteresis phenomenon were obtained; it was found that hysteresis improves the thermal performance of PCM-walls. The higher the hysteresis temperature difference the better the thermal performance, but there is a limit in the improvement of the thermal performance, which is achieved when the entire phase change process takes place at temperatures outside of the thermal comfort zone. Maximum improvements from 4% to 29% for air-conditioning and from 4% to 30% for non-air-conditioning, for a BioPCM wall with thicknesses from 6 mm to 18 mm, were found. Suggested criteria to achieve the maximum possible thermal performance of PCM-walls given a thickness and use condition were obtained. This work proposes the basis of a methodology to optimize simultaneously any pair of variables of a PCM-wall for different use conditions (AC, nAC, or a combined use of AC and nAC).

Keywords

thermal performance time-dependent PCM-wall hysteresis optimization 

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Notes

Acknowledgements

The authors acknowledge Dr. Jorge Rojas, Dr. Luis M. de la Cruz and Dr. Abel Hernández for useful discussions and valuable comments, as well as the support obtained through the project Laboratorio de Edificaciones Sustentables para desarrollo y evaluación de sistemas solares pasivos of the CeMIE-Sol, sponsored by the Fondo de Sustentabilidad Energética-SENER. Efraín Moreles acknowledges the support given by the Consejo Nacional de Ciencia y Tecnología CONACyT through the postgraduate scholarship program (grant number 299692) and the Universidad Nacional Autónoma de México UNAM to conduct his doctoral studies. The authors acknowledge the comments of reviewers, they helped to improve the presentation of this work.

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12273_2017_426_MOESM1_ESM.pdf (968 kb)
Hysteresis effects on the thermal performance of building envelope PCM-walls

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Copyright information

© Tsinghua University Press and Springer-Verlag GmbH Germany, part of Springer Nature 2018

Authors and Affiliations

  • Efraín Moreles
    • 1
  • Guadalupe Huelsz
    • 2
  • Guillermo Barrios
    • 2
  1. 1.Programa de Doctorado en Ingeniería, Universidad Nacional Autónoma de MéxicoInstituto de Energías RenovablesTemixcoMexico
  2. 2.Instituto de Energías RenovablesUniversidad Nacional Autónoma de MéxicoTemixcoMexico

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