Energy Saving Potentials of Phase Change Materials Applied to Lightweight Building Envelopes
Autor: | Jae Han Lim, Yoon Bok Seong |
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Jazyk: | angličtina |
Rok vydání: | 2013 |
Předmět: |
Control and Optimization
Materials science Passive cooling Cooling load Energy Engineering and Power Technology Thermodynamics phase change materials (PCMs) lightweight building envelope Sensible heat heating load lcsh:Technology jel:Q40 chemistry.chemical_compound cooling load Octadecane Latent heat jel:Q jel:Q43 HVAC jel:Q42 jel:Q41 jel:Q48 jel:Q47 Electrical and Electronic Engineering Engineering (miscellaneous) heatingload phase change temperature jel:Q49 Renewable Energy Sustainability and the Environment business.industry lcsh:T jel:Q0 jel:Q4 chemistry Air conditioning business Thermal energy Energy (miscellaneous) |
Zdroj: | Energies, Vol 6, Iss 10, Pp 5219-5230 (2013) Energies; Volume 6; Issue 10; Pages: 5219-5230 ENERGIES(6): 10 |
ISSN: | 1996-1073 |
Popis: | Phase change materials (PCMs) have been considered as an innovative technology that can reduce the peak loads and heating, ventilating and air conditioning (HVAC) energy consumption in buildings. Basically they are substances capable of storing or releasing thermal energy as latent heat. Because the amount of latent heat absorbed or released is much larger than the sensible heat, the application of PCMs in buildings has significant potential to reduce energy consumption. However, because each PCM has its own phase change temperature, which is the temperature at which latent heat is absorbed or released, it is important to use an appropriate PCM for the purpose of building envelope design. Therefore, this paper aims to investigate the energy saving potentials in buildings when various PCMs with different phase change temperatures are applied to a lightweight building envelope by analyzing the thermal load characteristics. As results, the annual heating load increased at every phase change temperature, but the peak heating load decreased by 3.19% with heptadecane (phase change temperature 21 °C), and the lowest indoor temperature increased by 0.86 °C with heptadecane (phase change temperature 21 °C). The annual cooling load decreased by 1.05% with dodecanol (phase change temperature 24 °C), the peak cooling load decreased by 1.30% with octadecane (phase change temperature 29 °C), and the highest indoor temperature dropped by 0.50 °C with octadecane (phase change temperature 29 °C). When the night ventilation was applied to the building HVAC system for better passive cooling performance, the annual cooling load decreased by 9.28% with dodecanol (phase change temperature 24 °C), the peak load decreased by 11.33% with octadecane (phase change temperature 29 °C), and the highest indoor temperature dropped by 0.85 °C with octadecane (phase change temperature 29 °C). |
Databáze: | OpenAIRE |
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