Efficient energy harvesting from PV Panel with reinforced hydrophilic nano-materials for eco-buildings

被引：22

作者：

Elnozahy A. ^{[1
]}

Abd-Elbary H. ^{[1
]}

Abo-Elyousr F.K. ^{[1
]}

机构：

[1] Department of Electrical Engineering, Faculty of Engineering, Assiut University, Assiut

来源：

Energy and Built Environment | 2024年 / 5卷 / 03期

关键词：

BIPV panels; Hydrophilic; Nano-coating; Self-cleaning; Techno-economic;

D O I：

10.1016/j.enbenv.2022.12.001

中图分类号：

学科分类号：

摘要：

The main target of this research is to allow solar PV to contribute economically to an on-grid energy-efficient building where the dust accumulation is a significant factor. Self-cleaning coatings such as hydrophobic or hydrophilic materials have recently been introduced to reduce dust deposition on building-integrated PV (BIPV) panels. The hydrophilic Nano-coated material is examined as a solution to decrease the impact of the dust on the BIPV panels and harvest more solar energy. An impartial comparison of the BIPV panels performance under natural dust conditions, manual cleaning, and hydrophilic nanomaterial coating is performed. Through an exhaustive and qualitative experimental analysis, the anti-reflection and anti-static properties of the utilized Nano-coated material are examined. The experimental results show that the hydrophilic Nano-coated material significantly improves the gathered maximum output power by 18% compared to the manually wiped panel. The calculated efficiencies of the Nano-coated, manual cleaning, and dusty panels are 11%, 9%, and 6%, respectively, which highlights the futureproofing of the Nano-coated solar panel. Compared to the dusty panels, the ecological and economical results show that the BIPV carbon emissions are desirably dropped by 11% while using Nano-coated PV panels and the payback period is reduced to 3.9 years, which is approximately 12.8% faster. © 2022

引用

页码：393 / 403

页数：10

共 53 条

[1]

Elnozahy A., Abdel Rahman A.K., Ali A.H.H., Abdel-Salam M., Ookawara S., Performance of a PV module integrated with standalone building in hot arid areas as enhanced by surface cooling and cleaning, Energy Build., 88, pp. 100-109, (2015)

[2]

Wu Z., Zhou Z., Alkatani M., Time-effective dust deposition analysis of pv modules based on finite element simulation for candidate site determination, IEEE access, 8, pp. 65137-65147, (2020)

[3]

Abdolahi A., Et al., Probabilistic multi-objective arbitrage of dispersed energy storage systems for optimal congestion management of active distribution networks including solar/wind/CHP hybrid energy system, J. Renewable Sustainable Energy, 10, 4, (2018)

[4]

Salehi J., Abdolahi A., Optimal scheduling of active distribution networks with penetration of PHEV considering congestion and air pollution using DR program, Sustainable Cities Soc., 51, (2019)

[5]

Taghizadegan N., Et al., Dominated GSO algorithm for optimal scheduling of renewable microgrids with penetration of electric vehicles and energy storages considering DRP, Int. J. Ambient Energy, pp. 1-12, (2022)

[6]

Ram J.P., Babu T.S., Rajasekar N., A comprehensive review on solar PV maximum power point tracking techniques, Renew. Sustain. Energy Rev., 67, pp. 826-847, (2017)

[7]

Wu Z., Hu Y., Wen J.X., Zhou F., Ye X., A review for solar panel fire accident prevention in large-scale PV applications, IEEE Access, 8, pp. 132466-132480, (2020)

[8]

Tian W., Wang Y., Ren J., Zhu L., Effect of urban climate on building integrated photovoltaics performance, Energy Convers. Manag., 48, 1, pp. 1-8, (2007)

[9]

Dabou R., Et al., Monitoring and performance analysis of grid connected photovoltaic under different climatic conditions in south Algeria, Energy Convers. Manag., 130, pp. 200-206, (2016)

[10]

Chaichan M.T., Kazem H.A., Experimental analysis of solar intensity on photovoltaic in hot and humid weather conditions, Int. J. Sci. Eng. Res., 7, 3, pp. 91-96, (2016)

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