Heat transfer Simulation of solar wall phase chang materials (PCM) for energy storage and optimization
محورهای موضوعی : Analytical and Numerical Methods in Mechanical DesignAli Akbar Hosseinjani 1 , Farshid Rashvand 2 , Hossein Zolghadr 3
1 - Department of Mechanical Engineering, Qazvin Branch, Islamic Azad University, Qazvin, Iran
2 - Faculty of Mechanical Engineering, Qazvin Branch, Islamic Azad University, Qazvin, Iran
3 - Faculty of Mechanical Engineering, Qazvin Branch, Islamic Azad University, Qazvin, Iran
کلید واژه: Phase change materials (PCM), Numerical Thermal energy storage, Computational fluid dynamics (CFD), latent heat,
چکیده مقاله :
phase change materials have a high capacity in thermal energy storage, these materials can be used to prevent the heat transfer into the building besides optimize and improve the performance of the refrigeration and air conditioning system. Adding phase change materials (PCM) to the building can improve the inside comfort temperature and save consumption energy of the building. In this article the parameters that affect the performance of PCM in the building walls, such as phase change temperature, latent heat, thickness, thermal conductivity, etc., have been investigated using ANSYS software. the numerical simulation of thermal energy storage in the solar walls of the building have investigated using phase change materials in different thicknesses with different heat flux rates. This wall is designed to capture the sun energy during the day, reducing energy consumption and optimizing it during peak times.
phase change materials have a high capacity in thermal energy storage, these materials can be used to prevent the heat transfer into the building besides optimize and improve the performance of the refrigeration and air conditioning system. Adding phase change materials (PCM) to the building can improve the inside comfort temperature and save consumption energy of the building. In this article the parameters that affect the performance of PCM in the building walls, such as phase change temperature, latent heat, thickness, thermal conductivity, etc., have been investigated using ANSYS software. the numerical simulation of thermal energy storage in the solar walls of the building have investigated using phase change materials in different thicknesses with different heat flux rates. This wall is designed to capture the sun energy during the day, reducing energy consumption and optimizing it during peak times.
[1] Lin, K., et al. Modeling and simulation of under-floor electric heating system with shape-stabilized PCM plates. 2004. 39(12): p. 1427-1434.
[2] Reddy, R.M., N. Nallusamy, and K.H.J.I.S.R.N. Reddy, The effect of PCM capsule material on the thermal energy storage system performance. 2014.
[3] Akeiber, Hussein, et al. "A review on phase change material (PCM) for sustainable passive cooling in building envelopes." Renewable and Sustainable Energy Reviews 60 (2016): 1470-1497.
[4] Lorsch, H., et al., Thermal energy storage for heating and air conditioning. 1976. 1: p. 69-81.
[5] Canbazoğlu, S., et al., Enhancement of solar thermal energy storage performance using sodium thiosulfate pentahydrate of a conventional solar water-heating system. 2005. 37(3): p. 235-242.
[6] Morcos, V.J.S. and w. technology, Investigation of a latent heat thermal energy storage system. 1990. 7(2-3): p. 197-202.
[7] Costa, M., et al., Numerical simulation of a latent heat thermal energy storage system with enhanced heat conduction. 1998. 39(3-4): p. 319-330.
[8] Lane, G.A., et al. Heat of fusion systems for solar energy storage. in Proc. Workshop on Solar Energy Storage Subsystems for the Heating and Cooling of Buildings. 1975. The University Press of Virginia Charlottesville.
[9] Soares, N.M.L., Thermal energy storage with phase change materials (PCMs) for the improvement of the energy performance of buildings. 2015, Universidade de Coimbra (Portugal).
[10] Sun, D., L.J.E. Wang, and buildings, Research on heat transfer performance of passive solar collector-storage wall system with phase change materials. 2016. 119: p. 183-188.
[11] Tyagi, V., et al., Phase change material based advance solar thermal energy storage systems for building heating and cooling applications: A prospective research approach. 2021. 47: p. 101318.
[12] McKenna, P., W. Turner, and D.JATE. Finn, Thermal energy storage using phase change material: Analysis of partial tank charging and discharging on system performance in a building cooling application. 2021. 198: p. 117437.
[13] Jin, Xing, et al. "Effects of PCM state on its phase change performance and the thermal performance of building walls." Building and environment 81 (2014): 334-339.
[14] Hawes, D., et al., Latent heat storage in building materials. 1993. 20(1): p. 77-86.
[15] Zhang, M., MA. Medina, and JB.J.I.j.o.e.r. King. Development of a thermally enhanced frame wall with phase-change materials for on-peak air conditioning demand reduction and energy savings in residential buildings. 2005. 29(9): p.795-809.
[16] Incropera, F. and D. DeWitt, Introduction to heat transfer. 1985.
[17] Humphries, W.R. and E.L. Griggs, A design handbook for phase change thermal control and energy storage devices. 1977.
[18] Bauer, C.A. and R.A. Wirtz. Thermal characteristics of a compact, passive thermal energy storage device. in ASME International Mechanical Engineering Congress and Exposition. 2000. American Society of Mechanical Engineers.
[19] Ravikumar, M., P.J.J.o.T. Srinivasan, and A.I. Technology, PHASE CHANGE MATERIAL AS A THERMAL ENERGY STORAGE MATERIAL FOR COOLING OF BUILDING. 2008. 4(6).
[20] Hembade, L., N. Neithalath, and S.D.J.J.O.E.E. Rajan, Understanding the energy implications of phase-change materials in concrete walls through finite-element analysis. 2014. 140(1): p. 04013009.
[21] Royon, L., et al., Optimization of PCM embedded in a floor panel developed for thermal management of the lightweight envelope of buildings. 2014. 82: p. 385-390.
[22] Ramakrishnan, S., et al., Parametric analysis for performance enhancement of phase change materials in naturally ventilated buildings. 2016. 124: p. 35- 45.
[23] Faraj, K., et al., Phase change material thermal energy storage systems for cooling applications in buildings: A review. 2020. 119: p. 109579.
[24] Zeinelabdein, R., S. Omer, and E.J.J.O.E.S. Mohamed, Parametric study of a sustainable cooling system integrating phase change material energy storage for buildings. 2020. 32: p. 101972.
[25] Xu, Y., et al., The numerical simulation of radiant floor cooling and heating system with double phase change energy storage and the thermal performance. 2021. 40: p. 102635.
[26] Hlanze, P., et al., In-duct phase change material-based energy storage to enhance building demand flexibility. 2022. 310: p. 118520.
[27] Rathore, P.K.S., et al., Thermal performance of the building envelope integrated with phase change material for thermal energy storage: an updated review. 2022: p. 103690.
[28] Andersson, B., et al. Computational fluid dynamics for engineers. 2011: Cambridge university press.
