Buildings, Vol. 15, Pages 590: Adaptability Analysis of Hollow Bricks with Phase-Change Materials Considering Thermal Performance and Cold Climate

Buildings, Vol. 15, Pages 590: Adaptability Analysis of Hollow Bricks with Phase-Change Materials Considering Thermal Performance and Cold Climate

Buildings, Vol. 15, Pages 590: Adaptability Analysis of Hollow Bricks with Phase-Change Materials Considering Thermal Performance and Cold Climate

Buildings doi: 10.3390/buildings15040590

Authors:
Yue Huang
Vladimir Nickolaevich Alekhin
Wentao Hu
Jinjin Pu

Composite phase-change materials (PCMs) exhibit significant potential for enhancing the thermal performance of building walls. However, previous studies have generally lacked detailed investigations of the performance of PCM-integrated walls under cold climate conditions. Therefore, in order to evaluate the thermal performance and wall adaptability of hollow bricks with composite PCMs in cold climates, a brick model was created by filling the hollow bricks with PCMs. Then a comparative test was conducted between the PCM-filled bricks and the conventional non-PCM-filled hollow bricks. The comparative experimental method and the thermal performance index evaluation method resulted in the following: (1) Compared with conventional hollow bricks, PCM-filled bricks showed an increase of approximately 0.99 °C in inner surface temperature and 3.85 °C in midsection temperature. This demonstrates that PCM-filled bricks can retard the rate of temperature drop, significantly enhancing the insulation performance of walls. This improvement contributes to enhance indoor thermal comfort and reduce energy consumption. (2) The temperature difference between the interior and exterior surfaces of the non-PCM-filled hollow bricks is 23.54 °C, which is 5.62 °C higher than that of the PCM-filled bricks. This indicates that bricks filled with PCMs possess superior heat storage capacity, effectively reducing indoor heat loss, which aligns with the principles of green building design. (3) Compared with the conventional non-PCM-filled hollow bricks, the heat flow on the inner surface of the PCM-filled bricks is significantly lower, with the average heat flow reduced by 8.57 W/m2. This suggests the ability of bricks filled with PCMs to moderate heat flux fluctuations through a “peak-shaving and valley-filling” effect, contributing to reduced energy consumption and enhanced occupant thermal comfort.

February 14, 2025 at 10:27AM
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Yue Huang