Development and Evaluation of a Solar-Powered Cooling System Integrated with Energy Storage

Bachaier Khir; İbrahim Uzun; Bahadır Gemicioğlu

doi:10.29137/ijerad.1506901

EN TR

Development and Evaluation of a Solar-Powered Cooling System Integrated with Energy Storage

Abstract

Energy study is conducted on the design of a cooling system powered by solar energy and used to perform the cooling process of a convenience store according to local environmental conditions. The main object of the study is to optimize the characteristic design parameters of the air conditioning system by utilizing solar energy as an alternative to conventional electrical energy. Energy and mass balances are established for the different parts of the convenience store to determine the heat gain by heat transfer in the building and the cooling load required to maintain a constant inside air temperature of 22°C. An air conditioning cycle with return air is considered to provide the required cooling capacity. Rechargeable storage system (battery) is defined to cover the no sunshine period. Technical research is included to determine the size and number of the photovoltaic solar panels required to provide the electrical power needed for the cooling system operation of and the batteriy charging. Suitable electrical and control equipment are selected from manufacturer catalogs.

Keywords

Cooling system, Solar PV system, heat gain, Heat transfer, Air conditioning, Electrical energy storage

Güneş Enerjili Soğutma Sistemi ve Enerji Depolama İle Entegrasyonun Geliştirilmesi ve Değerlendirilmesi

Abstract

Güneş enerjisiyle çalışan bir soğutma sisteminin tasarımı üzerine enerji çalışması yapılmış ve yerel çevresel koşullara göre bir bakkalın soğutma işlemini gerçekleştirmek üzere kullanılmıştır. Çalışmanın ana amacı, geleneksel elektrik enerjisi yerine güneş enerjisini kullanarak klima sisteminin karakteristik tasarım parametrelerini optimize etmektir. Bakkalın farklı bölgeleri için enerji ve kütle dengeleri kurulmuş, binada ısı transferi yoluyla ısı kazancı ve iç hava sıcaklığının sabit tutulması için gereken soğutma yükü belirlenmiştir (iç hava sıcaklığı 22°C). İhtiyaç duyulan soğutma kapasitesini sağlamak için geri dönüş havasıyla bir klima devresi ele alınmıştır. Güneş ışığı olmayan dönemleri kapsamak üzere şarj edilebilir depolama sistemi (pil) tanımlanmıştır. Soğutma sisteminin işletilmesi için gereken elektrik gücünü sağlamak için gereken fotovoltaik güneş panellerinin boyutu ve sayısı belirlemek için teknik araştırma yapılmış, uygun elektrik ve kontrol ekipmanları üretici kataloglarından seçilmiştir.

Keywords

Soğutma sistemi, Güneş PV sistemi, ısı kazancı, Isı transferi, Klima, Elektrik enerjisi depolama

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Details

Primary Language

English

Subjects

Energy Generation, Conversion and Storage (Excl. Chemical and Electrical)

Journal Section

Research Article

Authors

Bachaier Khir ^*
0009-0005-5992-9599
Türkiye

İbrahim Uzun
0000-0001-9725-2009
Türkiye

Bahadır Gemicioğlu
0000-0001-8403-1848
Türkiye

Early Pub Date

July 4, 2025

Publication Date

July 15, 2025

Submission Date

July 2, 2024

Acceptance Date

March 6, 2025

Published in Issue

Year 2025 Volume: 17 Number: 2

DOI

https://doi.org/10.29137/ijerad.1506901

IZ

https://izlik.org/JA33MT92NH

APA

Khir, B., Uzun, İ., & Gemicioğlu, B. (2025). Development and Evaluation of a Solar-Powered Cooling System Integrated with Energy Storage. International Journal of Engineering Research and Development, 17(2), 282-298. https://doi.org/10.29137/ijerad.1506901

AMA

1.Khir B, Uzun İ, Gemicioğlu B. Development and Evaluation of a Solar-Powered Cooling System Integrated with Energy Storage. IJERAD. 2025;17(2):282-298. doi:10.29137/ijerad.1506901

Chicago

Khir, Bachaier, İbrahim Uzun, and Bahadır Gemicioğlu. 2025. “Development and Evaluation of a Solar-Powered Cooling System Integrated With Energy Storage”. International Journal of Engineering Research and Development 17 (2): 282-98. https://doi.org/10.29137/ijerad.1506901.

EndNote

Khir B, Uzun İ, Gemicioğlu B (July 1, 2025) Development and Evaluation of a Solar-Powered Cooling System Integrated with Energy Storage. International Journal of Engineering Research and Development 17 2 282–298.

IEEE

[1]B. Khir, İ. Uzun, and B. Gemicioğlu, “Development and Evaluation of a Solar-Powered Cooling System Integrated with Energy Storage”, IJERAD, vol. 17, no. 2, pp. 282–298, July 2025, doi: 10.29137/ijerad.1506901.

ISNAD

Khir, Bachaier - Uzun, İbrahim - Gemicioğlu, Bahadır. “Development and Evaluation of a Solar-Powered Cooling System Integrated With Energy Storage”. International Journal of Engineering Research and Development 17/2 (July 1, 2025): 282-298. https://doi.org/10.29137/ijerad.1506901.

JAMA

1.Khir B, Uzun İ, Gemicioğlu B. Development and Evaluation of a Solar-Powered Cooling System Integrated with Energy Storage. IJERAD. 2025;17:282–298.

MLA

Khir, Bachaier, et al. “Development and Evaluation of a Solar-Powered Cooling System Integrated With Energy Storage”. International Journal of Engineering Research and Development, vol. 17, no. 2, July 2025, pp. 282-98, doi:10.29137/ijerad.1506901.

Vancouver

1.Bachaier Khir, İbrahim Uzun, Bahadır Gemicioğlu. Development and Evaluation of a Solar-Powered Cooling System Integrated with Energy Storage. IJERAD. 2025 Jul. 1;17(2):282-98. doi:10.29137/ijerad.1506901

Cited By

A Comparative Review of Conventional Mechanical and Solar‐Driven Cooling Technologies: Performance and Environmental Perspectives

Heat Transfer

https://doi.org/10.1002/htj.70279

Kırıkkale University, Faculty of Engineering and Natural Science, 71450 Yahşihan / Kırıkkale, Türkiye.

ijerad@kku.edu.tr