Design, performance and economic analysis of a nanofluid-based photovoltaic/thermal system for residential applications

• Published in: Energy conversion and management Vol. 149; pp. 467 - 484
• Main Authors: Lari, Muhammad O., Sahin, Ahmet Z.
• Format: Journal Article
• Language: English
• Published: Oxford Elsevier Ltd 01.10.2017; Elsevier Science Ltd
• Subjects: Absorber collector; Carbon dioxide; CFD; Computational fluid dynamics; Computer applications; Economic analysis; Electricity pricing; Feasibility studies; Fluid dynamics; Hydrodynamics; Nanofluids; Performance evaluation; Photovoltaic cells; Photovoltaic/thermal; Photovoltaics; Real building application; Residential buildings; Residential energy; Saudi Arabia; Silver/water nanofluid; Solar cells; Studies; Thermal and electrical efficiency; Thermal energy; Thermal properties; Thermodynamic properties; Dhahran Saudi Arabia; CFD; Absorber collector; Saudi Arabia; Economic analysis; Real building application; Photovoltaic/thermal; Silver/water nanofluid; Thermal and electrical efficiency
• ISSN: 0196-8904; 1879-2227
• DOI: 10.1016/j.enconman.2017.07.045

•A nanofluid based photovoltaic/thermal system is designed and analyzed.•CFD was used to select the best possible thermal collector configuration.•A hybrid, parallel-serpentine collector provided up to 8.5% more electrical output.•Use of silver/water nanofluid resulted in a maximum of 18% more thermal output.•The system results in 82% saving in energy cost, relative to domestic energy price. Photovoltaic thermal systems (PVT) have higher electrical efficiencies than photovoltaic systems because they bring down solar cell temperature, thereby increasing the electrical yield of solar cells, while simultaneously providing thermal energy in the form of hot fluid. Use of nanofluids in such systems have become increasingly popular due to the superior thermal properties of nanofluids. A nanofluid-cooled photovoltaic/thermal system is designed to meet the electrical demands of a residential building for the climate of Dhahran, Saudi Arabia. Optimum collector design is selected through computational fluid dynamics after which daily and yearly performance evaluation of the system is analytically performed through Engineering Equation Solver. Additionally, an economic feasibility study is performed to demonstrate the financial benefits of the proposed system. Results show an increase of 8.5% in the electrical output of a water-cooled PVT system over a PV system and an increase of 13% in the thermal output of a nanofluid-cooled PVT system over a water-cooled PVT system. Furthermore, the cost of energy from the proposed system is 82% less than the domestic price of electricity in Saudi Arabia and the system could prevent the release of 16,974.57 tonnes of CO2 into the atmosphere.