A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Modeling and simulation on the performance of a novel double shape-stabilized phase change materials wallboard
https://orcid.org/0000-0003-4142-8612
Highlights Building envelope integrated with double layers SSPCMs. The new wall system is for year-round application. Energy and thermal performance are analyzed. Effects of melting temperature and thickness are studied. Energy saving and peak load reduction for cooling/heating are investigated.
Abstract The structure of a new wall system was that of a three-layer sandwich-type panel with external/internal layer consisting of shape-stabilized phase change material (SSPCM) wallboard and middle layer consisting of conventional concrete. The external layer was active in hot seasons and the internal layer was active in cold seasons. An office room integrated with the novel double SSPCMs wallboard with a splitting air-conditioner was used for modeling and simulation test platform. Studies were conducted to investigate the effects of the novel double SSPCMs and different parameters on the energy and thermal performance in typical climate area with hot summer and cold winter (Wuhan city, China). Test results showed that the recommended thicknesses of external and internal SSPCM wallboard were 30–60mm. With the recommended thickness, the annual energy savings for cooling were 3.4–3.9%. The peak load reductions for cooling were 3.1–3.8%. The annual energy savings for heating were 14.8–18.8%. The peak load reductions for heating were 8.6–11.3%. The external layer was effective on reducing annual energy demand and peak load of cooling in hot seasons. The internal layer was effective on reducing the indoor temperature fluctuation in cold seasons.
Modeling and simulation on the performance of a novel double shape-stabilized phase change materials wallboard
https://orcid.org/0000-0003-4142-8612
Highlights Building envelope integrated with double layers SSPCMs. The new wall system is for year-round application. Energy and thermal performance are analyzed. Effects of melting temperature and thickness are studied. Energy saving and peak load reduction for cooling/heating are investigated.
Abstract The structure of a new wall system was that of a three-layer sandwich-type panel with external/internal layer consisting of shape-stabilized phase change material (SSPCM) wallboard and middle layer consisting of conventional concrete. The external layer was active in hot seasons and the internal layer was active in cold seasons. An office room integrated with the novel double SSPCMs wallboard with a splitting air-conditioner was used for modeling and simulation test platform. Studies were conducted to investigate the effects of the novel double SSPCMs and different parameters on the energy and thermal performance in typical climate area with hot summer and cold winter (Wuhan city, China). Test results showed that the recommended thicknesses of external and internal SSPCM wallboard were 30–60mm. With the recommended thickness, the annual energy savings for cooling were 3.4–3.9%. The peak load reductions for cooling were 3.1–3.8%. The annual energy savings for heating were 14.8–18.8%. The peak load reductions for heating were 8.6–11.3%. The external layer was effective on reducing annual energy demand and peak load of cooling in hot seasons. The internal layer was effective on reducing the indoor temperature fluctuation in cold seasons.
Modeling and simulation on the performance of a novel double shape-stabilized phase change materials wallboard
https://orcid.org/0000-0003-4142-8612
Highlights Building envelope integrated with double layers SSPCMs. The new wall system is for year-round application. Energy and thermal performance are analyzed. Effects of melting temperature and thickness are studied. Energy saving and peak load reduction for cooling/heating are investigated.
Abstract The structure of a new wall system was that of a three-layer sandwich-type panel with external/internal layer consisting of shape-stabilized phase change material (SSPCM) wallboard and middle layer consisting of conventional concrete. The external layer was active in hot seasons and the internal layer was active in cold seasons. An office room integrated with the novel double SSPCMs wallboard with a splitting air-conditioner was used for modeling and simulation test platform. Studies were conducted to investigate the effects of the novel double SSPCMs and different parameters on the energy and thermal performance in typical climate area with hot summer and cold winter (Wuhan city, China). Test results showed that the recommended thicknesses of external and internal SSPCM wallboard were 30–60mm. With the recommended thickness, the annual energy savings for cooling were 3.4–3.9%. The peak load reductions for cooling were 3.1–3.8%. The annual energy savings for heating were 14.8–18.8%. The peak load reductions for heating were 8.6–11.3%. The external layer was effective on reducing annual energy demand and peak load of cooling in hot seasons. The internal layer was effective on reducing the indoor temperature fluctuation in cold seasons.
Modeling and simulation on the performance of a novel double shape-stabilized phase change materials wallboard
Zhu, Na (author) / Liu, Pengpeng (author) / Hu, Pingfang (author) / Liu, Fuli (author) / Jiang, Zhangning (author)
Energy and Buildings ; 107 ; 181-190
2015-07-20
10 pages
Article (Journal)
Electronic Resource
English