Abstract
Phase change material (PCM) applied to roofs can weak external heat entering the room to reduce air-conditioning energy consumption. In this study, three forms of macro-encapsulated PCM roofs with different PCMs (RT27, RT31, RT35HC, PT37) are proposed. The effects of PCM thickness, the encapsulation forms, and different PCMs on the thermal performance of the roof are discussed in Moroccan semi-arid and Mediterranean climates. The results show that as the PCM thickness increases, the peak temperature attenuation of the roof inner surface decreases. In two climates, the pure PCM layer among the three encapsulation forms (i.e. pure PCM layer, PCM in aluminum tubes, PCM in triangular aluminum) is the easiest to appear the phenomenon of insufficient heat storage and release, while the reduction of the peak inner surface temperature and time lag is the most satisfying. For the PCM in the aluminum tube, phase change time is the shortest and the latent heat utilization ratio is the highest, while thermal regulation performance is the least satisfying. The PCM in triangular aluminum can improve the latent heat utilization ratio significantly, and its thermal regulation performance is in the middle. In semi-arid climate, the time lag increases with phase change temperature increasing. The time lag could reach up to 6 h with 37 °C phase transition temperature. In Mediterranean climate, the longest time lag with RT31 is 5 h, while the lowest peak inner surface temperature appears with RT27. The obtained conclusions could provide guidance for the application of PCM roofs in these two climates.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Aadmi M, Karkri M, El Hammouti M (2015). Heat transfer characteristics of thermal energy storage for PCM (phase change material) melting in horizontal tube: Numerical and experimental investigations. Energy, 85: 339–352.
Aderee (2014). Règelement thermique de construction au Maroc. (in French)
Ahmed MMS, Radwan A, Serageldin AA, et al. (2021). The thermal potential of a new multifunctional sliding window. Solar Energy, 226: 389–407.
Aketouane Z, Malha M, Bruneau D, et al. (2018). Energy savings potential by integrating Phase Change Material into hollow bricks: The case of Moroccan buildings. Building Simulation, 11: 1109–1122.
Alawadhi EM, Alqallaf HJ (2011). Building roof with conical holes containing PCM to reduce the cooling load: Numerical study. Energy Conversion and Management, 52: 2958–2964.
Alqallaf HJ, Alawadhi EM (2013). Concrete roof with cylindrical holes containing PCM to reduce the heat gain. Energy and Buildings, 61: 73–80.
Al-Shannaq R, Young B, Farid M (2019). Cold energy storage in a packed bed of novel graphite/PCM composite spheres. Energy, 171: 296–305.
Al-Yasiri Q, Szabó M (2021a). Case study on the optimal thickness of phase change material incorporated composite roof under hot climate conditions. Case Studies in Construction Materials, 14: e00522.
Al-Yasiri Q, Szabó M (2021b). Experimental evaluation of the optimal position of a macroencapsulated phase change material incorporated composite roof under hot climate conditions. Sustainable Energy Technologies and Assessments, 45: 101121.
Arıcı M, Bilgin F, Nižetić S, et al. (2020). PCM integrated to external building walls: An optimization study on maximum activation of latent heat. Applied Thermal Engineering, 165: 114560.
Arumugam C, Shaik S (2021). Air-conditioning cost saving and CO2 emission reduction prospective of buildings designed with PCM integrated blocks and roofs. Sustainable Energy Technologies and Assessments, 48: 101657.
Bellan S, Alam TE, González-Aguilar J, et al. (2015). Numerical and experimental studies on heat transfer characteristics of thermal energy storage system packed with molten salt PCM capsules. Applied Thermal Engineering, 90: 970–979.
Ben Romdhane S, Amamou A, Ben Khalifa R, et al. (2020). A review on thermal energy storage using phase change materials in passive building applications. Journal of Building Engineering, 32: 101563.
Bhamare DK, Rathod MK, Banerjee J (2020). Numerical model for evaluating thermal performance of residential building roof integrated with inclined phase change material (PCM) layer. Journal of Building Engineering, 28: 101018.
Cui H, Tang W, Qin Q, et al. (2017). Development of structural-functional integrated energy storage concrete with innovative macro-encapsulated PCM by hollow steel ball. Applied Energy, 185: 107–118.
DOE (2012). Buildings Energy Data Book. U.S. Department of Energy (DOE).
Erlbeck L, Schreiner P, Schlachter K, et al. (2018). Adjustment of thermal behavior by changing the shape of PCM inclusions in concrete blocks. Energy Conversion and Management, 158: 256–265.
Fadl M, Eames PC (2019). Numerical investigation of the influence of mushy zone parameter Amush on heat transfer characteristics in vertically and horizontally oriented thermal energy storage systems. Applied Thermal Engineering, 151: 90–99.
IEA (2019). 2019 Global status report for buildings and construction: Towards a zero-emission, efficient and resilient buildings and construction sector. International Energy Agency, UN Environment Programme. Available at https://webstore.iea.org/2019/.
Jiang X, Luo R, Peng F, et al. (2015). Synthesis, characterization and thermal properties of paraffin microcapsules modified with nano-Al2O3. Applied Energy, 137: 731–737.
Joulin A, Younsi Z, Zalewski L, et al. (2011). Experimental and numerical investigation of a phase change material: Thermal-energy storage and release. Applied Energy, 88: 2454–2462.
Kharbouch Y, Ouhsaine L, Mimet A, et al. (2018). Thermal performance investigation of a PCM-enhanced wall/roof in northern Morocco. Building Simulation, 11: 1083–1093.
Kharbouch Y, Ouhsaine L, Mimet A, et al. (2018). Thermal performance investigation of a PCM-enhanced wall/roof in northern Morocco. Building Simulation, 11: 1083–1093.
Kong X, Lu S, Li Y, et al. (2014). Numerical study on the thermal performance of building wall and roof incorporating phase change material panel for passive cooling application. Energy and Buildings, 81: 404–415.
Kontoleon KJ, Stefanidou M, Saboor S, et al. (2021). Defensive behaviour of building envelopes in terms of mechanical and thermal responsiveness by incorporating PCMs in cement mortar layers. Sustainable Energy Technologies and Assessments, 47: 101349.
Konuklu Y, Ostry M, Paksoy HO, et al. (2015). Review on using microencapsulated phase change materials (PCM) in building applications. Energy and Buildings, 106: 134–155.
Lei J, Yang J, Yang E (2016). Energy performance of building envelopes integrated with phase change materials for cooling load reduction in tropical Singapore. Applied Energy, 162: 207–217.
Li ZX, Al-Rashed AAAA, Rostamzadeh M, et al. (2019). Heat transfer reduction in buildings by embedding phase change material in multi-layer walls: Effects of repositioning, thermophysical properties and thickness of PCM. Energy Conversion and Management, 195: 43–56.
Mahdaoui M, Hamdaoui S, Ait Msaad A, et al. (2021). Building bricks with phase change material (PCM): Thermal performances. Construction and Building Materials, 269: 121315.
Marin P, Saffari M, de Gracia A, et al. (2016). Energy savings due to the use of PCM for relocatable lightweight buildings passive heating and cooling in different weather conditions. Energy and Buildings, 129: 274–283.
Mohamed Moussa EI, Karkri M (2019). A numerical investigation of the effects of metal foam characteristics and heating/cooling conditions on the phase change kinetic of phase change materials embedded in metal foam. Journal of Energy Storage, 26: 100985.
Mourid A, Alami ME, Najam M (2016). Passive study of energy efficiency of a building with PCM on the roof during summer in Casablanca. Journal of Power and Energy Engineering, 4: 26–37.
Mourid A, El Alami M (2017). Thermal behavior of a building provided with phase-change materials on the roof and exposed to solar radiation. Journal of Solar Energy Engineering, 139(6): 061012.
Mourid A, El Alami M, Kuznik F (2018). Experimental investigation on thermal behavior and reduction of energy consumption in a real scale building by using phase change materials on its envelope. Sustainable Cities and Society, 41: 35–43.
Nahar NM, Sharma P, Purohit MM (2003). Performance of different passive techniques for cooling of buildings in arid regions. Building and Environment, 38: 109–116.
Park JH, Lee J, Wi S, et al. (2019). Optimization of phase change materials to improve energy performance within thermal comfort range in the South Korean climate. Energy and Buildings, 185: 12–25.
Park JH, Wi S, Chang SJ, et al. (2020). Analysis of energy retrofit system using latent heat storage materials applied to residential buildings considering climate impacts. Applied Thermal Engineering, 169: 114904.
Pasupathy A, Velraj R (2008). Effect of double layer phase change material in building roof for year round thermal management. Energy and Buildings, 40: 193–203.
Qu Y, Zhou D, Xue F, Cui L (2021). Multi-factor analysis on thermal comfort and energy saving potential for PCM-integrated buildings in summer. Energy and Buildings, 241: 110966.
Regin AF, Solanki SC, Saini JS (2008). Heat transfer characteristics of thermal energy storage system using PCM capsules: a review. Renewable and Sustainable Energy Reviews, 12: 2438–2458.
Saffari M, de Gracia A, Fernández C, et al. (2017). Simulation-based optimization of PCM melting temperature to improve the energy performance in buildings. Applied Energy, 202: 420–434.
Song M, Niu F, Mao N, et al. (2018). Review on building energy performance improvement using phase change materials. Energy and Buildings, 158: 776–793.
Xamán J, Rodriguez-Ake A, Zavala-Guillén I, et al. (2020). Thermal performance analysis of a roof with a PCM-layer under Mexican weather conditions. Renewable Energy, 149: 773–785.
Yu J, Yang Q, Ye H, et al. (2020). Thermal performance evaluation and optimal design of building roof with outer-layer shape-stabilized PCM. Renewable Energy, 145: 2538–2549.
Zhang Y, Bozorg MV, Torres JF, et al. (2022). Dynamic melting of encapsulated PCM in various geometries driven by natural convection of surrounding air: A modelling-based parametric study. Journal of Energy Storage, 48: 103975.
Zhou D, Zhao CY, Tian Y (2012). Review on thermal energy storage with phase change materials (PCMs) in building applications. Applied Energy, 92: 593–605.
Acknowledgements
This study was supported by a grant from National Key R&D Program of China (No. 2020YFE0200300). The authors gratefully acknowledge financial support from China Scholarship Council.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Huang, Y., Yang, S., Aadmi, M. et al. Numerical analysis on phase change progress and thermal performance of different roofs integrated with phase change material (PCM) in Moroccan semi-arid and Mediterranean climates. Build. Simul. 16, 69–85 (2023). https://doi.org/10.1007/s12273-022-0922-z
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s12273-022-0922-z