Numerical and Experimental Assessment of a PCM Integrated Solar Chimney

J. Carlos Frutos Dordelly; M. Coillot; M. El Mankibi; R. Enríquez Miranda; M. José Jimenez; J. Arce Landa

Open Science Index

Commenced in January 2007

Frequency: Monthly

Edition: International

Publications Count: 31106

10008786

Numerical and Experimental Assessment of a PCM Integrated Solar Chimney

Authors:

J. Carlos Frutos Dordelly, M. Coillot, M. El Mankibi, R. Enríquez Miranda, M. José Jimenez, J. Arce Landa

Abstract:

Natural ventilation systems have increasingly been the subject of research due to rising energetic consumption within the building sector and increased environmental awareness. In the last two decades, the mounting concern of greenhouse gas emissions and the need for an efficient passive ventilation system have driven the development of new alternative passive technologies such as ventilated facades, trombe walls or solar chimneys. The objective of the study is the assessment of PCM panels in an in situ solar chimney for the establishment of a numerical model. The PCM integrated solar chimney shows slight performance improvement in terms of mass flow rate and external temperature and outlet temperature difference. An increase of 11.3659 m³/h can be observed during low wind speed periods. Additionally, the surface temperature across the chimney goes beyond 45 °C and allows the activation of PCM panels.

Keywords:

Energy storage, passive ventilation, phase changing materials, solar chimney, solar energy.

Digital Object Identifier (DOI):

doi.org/10.5281/zenodo.10.5281/zenodo.1316257

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References:

[1] N. K. Bansal, R. Mathur, and M. S. Bhandari, “Solar chimney for enhanced stack ventilation,” Build. Environ., vol. 28, no. 3, pp. 373–377, 1993.
[2] M. M. AboulNaga and S. N. Abdrabboh, “Improving night ventilation into low-rise buildings in hot-arid climates exploring a combined wall-roof solar chimney,” Renew. Energy, vol. 19, no. 1–2, pp. 47–54, 2000.
[3] R. Khanal and C. Lei, “A numerical investigation of buoyancy induced turbulent air flow in an inclined passive wall solar chimney for natural ventilation,” Energy Build., vol. 93, pp. 217–226, 2015.
[4] Z. D. Chen, P. Bandopadhayay, J. Halldorsson, C. Byrjalsen, P. Heiselberg, and Y. Li, “An experimental investigation of a solar chimney model with uniform wall heat flux,” Build. Environ., vol. 38, no. 7, pp. 893–906, 2003.
[5] B. Liu, X. Ma, X. Wang, C. Dang, Q. Wang, and R. Bennacer, “Experimental study of the chimney effect in a solar hybrid double wall,” Sol. Energy, vol. 115, pp. 1–9, 2015.
[6] S. Duan, C. Jing, and E. Long, “Transient flows in displacement ventilation enhanced by solar chimney and fan,” Energy Build., vol. 103, pp. 124–130, 2015.
[7] M. J. Suárez-López, A. M. Blanco-Marigorta, A. J. Gutiérrez-Trashorras, J. Pistono-Favero, and E. Blanco-Marigorta, “Numerical simulation and exergetic analysis of building ventilation solar chimneys,” Energy Convers. Manag., vol. 96, pp. 1–11, 2015.
[8] M. Rabani, V. Kalantar, A. A. Dehghan, and A. K. Faghih, “Empirical investigation of the cooling performance of a new designed Trombe wall in combination with solar chimney and water spraying system,” Energy Build., vol. 102, pp. 45–57, 2015.
[9] M. H. Naraghi and S. Blanchard, “Twenty-four hour simulation of solar chimneys,” Energy Build., vol. 94, pp. 219–226, 2015.
[10] J. Arce, M. J. Jiménez, R. Enríquez, L. Castillo, G. Álvarez, and M. R. Heras, “Thermal performance analysis of a solar chimney , based on the experimental study of the main driving variables in a physical prototype,” Pap. Conf., no. October, pp. 385–395, 2015.
[11] J. C. Frutos Dordelly, M. Coillot, M. El Mankibi, R. Enriquez, M. J. Jimenez, and J. A. Landa, “Active Solar Chimney ( ASC ) - Numerical and experimental study of energy storage and evaporative cooling,” World Sol. Congr. Abu Dhabi, 2017.
[12] J. Arce, J. P. Xaman, G. Alvarez, M. J. Jiménez, and M. R. Heras, “A parametric study of conjugate heat transfer of solar chimney,” Proc. ASME 3rd Int. Conf. Energy Sustain. 2009, ES2009, vol. 1, pp. 605–612, 2009.
[13] Y. Li and S. Liu, “Numerical study on thermal behaviors of a solar chimney incorporated with PCM,” Energy Build., vol. 80, pp. 406–414, 2014.
[14] P. A. Mirzaei and F. Haghighat, “Modeling of phase change materials for applications in whole building simulation,” Renew. Sustain. Energy Rev., vol. 16, no. 7, pp. 5355–5362, 2012.
[15] D. Zhou, C. Y. Zhao, and Y. Tian, “Review on thermal energy storage with phase change materials (PCMs) in building applications,” Appl. Energy, vol. 92, pp. 593–605, 2012.
[16] M. Kheradmand, M. Azenha, J. L. B. de Aguiar, and J. Castro-Gomes, “Experimental and numerical studies of hybrid PCM embedded in plastering mortar for enhanced thermal behaviour of buildings,” Energy, vol. 94, pp. 250–261, 2016.

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