Roofing Solar Panels of Planar and Concentrator Designs

Roofing Solar Panels of Planar and Concentrator Designs

Vladimir Panchenko
Copyright: © 2020 |Pages: 21
DOI: 10.4018/IJEOE.2020100102
OnDemand:
(Individual Articles)
Available
$37.50
Current Special Offers
No Current Special Offers
TOTAL SAVINGS: $37.50

Abstract

Solar roofing panels fulfill both building protective functions and energy generating ones. The composition of the substrate of the solar roofing panel includes secondary raw materials, which has a positive effect on the environment. To increase the electrical efficiency and also to obtain thermal energy in the form of warm water, it was proposed to create a photovoltaic thermal roofing panel. For this purpose, the presented article describes the method of creating a three-dimensional model of solar photovoltaic thermal modules in a computer-aided design system. The article also proposes a method for manufacturing a prototype body for a solar roofing panel, manufactured using additive technologies, which will significantly reduce costs at the initial stage of creating a prototype due to the possibility of operational changes to a three-dimensional model followed by printing a modified and optimized model. To reduce the number of photovoltaic cells and the cost of a solar roofing panel, it is proposed to use a solar concentrator in the panel.
Article Preview
Top

Background

Various designs and studies of PVT modules are considered in the works (Kharchenko, Nikitin, Tikhonov & Gusarov, 2013; Zharkov, 2014; Kamilov, Muminov & Tursunov, 2008; Hosseini, Hosseini & Khorasanizadeh, 2011; Rawat, Debbarma, Mehrotra at all, 2014; Buonomano, Calise & Vicidimini, 2016; Strebkov, Panchenko & Filippchenkova, 2015; Tiwari. & Sodha, 2006; Rosell, Vallverdu, Lechon & Ibanez, 2005; Ibrahim, Jin, Daghigh, Salleh, Othman, Ruslan et al., 2009; Othman, Ruslan, Sopian & Jin, 2009; Sevela & Olesen, 2013; Ibrahim, Othman, Ruslan, Mat & Sopian, 2011; Dubey & Tay, 2012; Alfegi, Sopian, Othman & Yatim, 2007; Strebkov, Mayorov & Panchenko, 2013; Kharchenko, Panchenko, Tikhonov & Vasant, 2018; Kharchenko, 2014). For theoretical studies of PVT modules, mathematical modeling is widely used (Zakharchenko, Licea-Jiménez, Pérez-García, Vorobeiv, Dehesa Carrasco, Pérez-Robels et al., 2004; Bergene & Lovvik, 1995; Florschuetz, 1979; Sandnes & Rekstad, 2002). It is not surprising that in the reviewed papers attention is paid to the development of the optimal design of the heat-generating part of the PVT module, since the optimal design of such a module will ensure high efficiency of the photovoltaic installation and high output thermal power.

Complete Article List

Search this Journal:
Reset
Volume 12: 1 Issue (2024): Forthcoming, Available for Pre-Order
Volume 11: 4 Issues (2022): 2 Released, 2 Forthcoming
Volume 10: 4 Issues (2021)
Volume 9: 4 Issues (2020)
Volume 8: 4 Issues (2019)
Volume 7: 4 Issues (2018)
Volume 6: 4 Issues (2017)
Volume 5: 4 Issues (2016)
Volume 4: 4 Issues (2015)
Volume 3: 4 Issues (2014)
Volume 2: 4 Issues (2013)
Volume 1: 4 Issues (2012)
View Complete Journal Contents Listing