Enhancing heat efficiency in arid environments using a PVT collector for revealed facade shelter

Mohamed Cherif Benzid; Boubekeur Dokkar; Abdelghani Boubekri

doi:10.14744/thermal.0000922

Enhancing heat efficiency in arid environments using a PVT collector for revealed facade shelter

Abstract

In Ouargla neighboring (Algeria), the harsh climate conditions and the isolation of agricultural areas pose some difficulties for developing agriculture. For lightening climatic constraints, thermal comfort in farmer homes is required. The present study investigated the thermal behavior in a 3D model of an existing earth-sheltered room using Ansys Software. To improve room heating on the coldest winter day, different room designs are investigated. The variant equipped with a photovoltaic-thermal (PVT) solar collector shows significant thermal comfort, where for an ambient temperature of around 4°C, the indoor temperature in the living space reaches about 24°C. Also, the PVT system has a low initial cost compared to a heat pump, where the gap reaches 1460 euros. In addition, the long-term exploitation of discovered façade shelters achieves an appreciable benefit against the mode of farmers’ transportation between the city and the farm.

Keywords

References

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Details

Primary Language

English

Subjects

Fluid Mechanics and Thermal Engineering (Other)

Journal Section

Research Article

Authors

Mohamed Cherif Benzid This is me
0000-0001-5943-6667
Algeria

Boubekeur Dokkar ^* This is me
0000-0002-2206-4027
Algeria

Abdelghani Boubekri
0000-0002-1551-8000
Algeria

Publication Date

March 24, 2025

Submission Date

April 3, 2024

Acceptance Date

July 9, 2024

Published in Issue

Year 2025 Volume: 11 Number: 2

DOI

https://doi.org/10.14744/thermal.0000922

IZ

https://izlik.org/JA75MW27RL

Cite

RIS / Bibtex

APA

Benzid, M. C., Dokkar, B., & Boubekri, A. (2025). Enhancing heat efficiency in arid environments using a PVT collector for revealed facade shelter. Journal of Thermal Engineering, 11(2), 390-406. https://doi.org/10.14744/thermal.0000922

AMA

1.Benzid MC, Dokkar B, Boubekri A. Enhancing heat efficiency in arid environments using a PVT collector for revealed facade shelter. Journal of Thermal Engineering. 2025;11(2):390-406. doi:10.14744/thermal.0000922

Chicago

Benzid, Mohamed Cherif, Boubekeur Dokkar, and Abdelghani Boubekri. 2025. “Enhancing Heat Efficiency in Arid Environments Using a PVT Collector for Revealed Facade Shelter”. Journal of Thermal Engineering 11 (2): 390-406. https://doi.org/10.14744/thermal.0000922.

EndNote

Benzid MC, Dokkar B, Boubekri A (March 1, 2025) Enhancing heat efficiency in arid environments using a PVT collector for revealed facade shelter. Journal of Thermal Engineering 11 2 390–406.

IEEE

[1]M. C. Benzid, B. Dokkar, and A. Boubekri, “Enhancing heat efficiency in arid environments using a PVT collector for revealed facade shelter”, Journal of Thermal Engineering, vol. 11, no. 2, pp. 390–406, Mar. 2025, doi: 10.14744/thermal.0000922.

ISNAD

Benzid, Mohamed Cherif - Dokkar, Boubekeur - Boubekri, Abdelghani. “Enhancing Heat Efficiency in Arid Environments Using a PVT Collector for Revealed Facade Shelter”. Journal of Thermal Engineering 11/2 (March 1, 2025): 390-406. https://doi.org/10.14744/thermal.0000922.

JAMA

1.Benzid MC, Dokkar B, Boubekri A. Enhancing heat efficiency in arid environments using a PVT collector for revealed facade shelter. Journal of Thermal Engineering. 2025;11:390–406.

MLA

Benzid, Mohamed Cherif, et al. “Enhancing Heat Efficiency in Arid Environments Using a PVT Collector for Revealed Facade Shelter”. Journal of Thermal Engineering, vol. 11, no. 2, Mar. 2025, pp. 390-06, doi:10.14744/thermal.0000922.

Vancouver

1.Mohamed Cherif Benzid, Boubekeur Dokkar, Abdelghani Boubekri. Enhancing heat efficiency in arid environments using a PVT collector for revealed facade shelter. Journal of Thermal Engineering. 2025 Mar. 1;11(2):390-406. doi:10.14744/thermal.0000922