eprintid: 18091 rev_number: 2 eprint_status: archive userid: 1 dir: disk0/00/01/80/91 datestamp: 2024-06-04 14:10:12 lastmod: 2024-06-04 14:10:12 status_changed: 2024-06-04 14:01:19 type: article metadata_visibility: show creators_name: Nazri, N.S. creators_name: Fudholi, A. creators_name: Solomin, E. creators_name: Arifin, M. creators_name: Yazdi, M.H. creators_name: Suyono, T. creators_name: Priandana, E.R. creators_name: Mustapha, M. creators_name: Hamsan, M.H. creators_name: Hussain, A.H. creators_name: Khaidzir, M.F.S. creators_name: Ali Zaini, M.I. creators_name: Rosli, N.N. creators_name: Mohammad, M. creators_name: Sopian, K. title: Analytical and experimental study of hybrid photovoltaic�thermal�thermoelectric systems in sustainable energy generation ispublished: pub keywords: Conversion efficiency; Energy efficiency; Integration; Inverse problems; Solar panels; Solar power generation; Solar thermal energy; Thermoelectricity, Air collectors; Energy analysis; Hybrid photovoltaics; Performance; Photovoltaic thermals; Photovoltaic/thermal systems; Sustainable energy; Systems performance; Thermoelectric; Thermoelectric systems, Hybrid systems note: cited By 2 abstract: A new hybrid system, known as photovoltaic�thermal�thermoelectric (PVT-TE), has been proposed to enhance the conversion efficiency of PV cells by incorporating an intelligent thermal management system, which leverages the dual functions of thermoelectric (TE). This study aims to explore the potential for creating a hybrid system that is more efficient and offers improved performance than standalone photovoltaic thermal (PVT) systems. The key parameters for the creation of a hybrid system were analysed, and the theoretical and experimental results were compared to validate the model. The performance of the PVT-TE collector was evaluated through a steady-state analysis using a one dimensional (1D) mathematical model. Energy balance equations were solved using Microsoft Excel and inverse matrix method. Experiments on PVT and PVT-TE collectors were examined at a solar radiation intensity of 593.16 W/m2. The air mass flow rate was set at 0.009, 0.021, 0.039, 0.069 and 0.095 kg/s for specific radiation intensity. The thermal and electrical performance of the hybrid system was higher than that of the conventional PVT system. The PVT-TE system combines photovoltaic and thermoelectric components, including a thermoelectric module and an air collector. The integration improves system efficiency and performance, surpassing previous research efforts. The PVT-TE system with an air collector has innovative features including efficient thermal-electric conversion, integrated component utilisation, and air collector integration. The overall efficiency of the hybrid system was 7.05�31.13 higher than the theoretical values and 9.64�34.83 higher than the experimental values. The increase in the output power of the hybrid system was also higher by 32.59�55.93. The findings indicate that the integration thermoelectric (TE) with PV cells has the potential to enhance solar thermal systems' performance. This study provides the basis for further analysis and optimisation of PVT-TE hybrid systems. © 2023 The Authors date: 2023 official_url: https://www.scopus.com/inward/record.uri?eid=2-s2.0-85173560834&doi=10.1016%2fj.csite.2023.103522&partnerID=40&md5=1a52c16da785ac5367f949f797b44648 id_number: 10.1016/j.csite.2023.103522 full_text_status: none publication: Case Studies in Thermal Engineering volume: 51 refereed: TRUE citation: Nazri, N.S. and Fudholi, A. and Solomin, E. and Arifin, M. and Yazdi, M.H. and Suyono, T. and Priandana, E.R. and Mustapha, M. and Hamsan, M.H. and Hussain, A.H. and Khaidzir, M.F.S. and Ali Zaini, M.I. and Rosli, N.N. and Mohammad, M. and Sopian, K. (2023) Analytical and experimental study of hybrid photovoltaic�thermal�thermoelectric systems in sustainable energy generation. Case Studies in Thermal Engineering, 51.