Now showing 1 - 2 of 2
  • Placeholder Image
    Publication
    Pathways toward high-efficiency solar photovoltaic thermal management for electrical, thermal and combined generation applications: A critical review
    (01-03-2022)
    Madurai Elavarasan, Rajvikram
    ;
    Mudgal, Vijay
    ;
    Selvamanohar, Leoponraj
    ;
    Wang, Kai
    ;
    Huang, Gan
    ;
    Shafiullah, G. M.
    ;
    Markides, Christos N.
    ;
    ;
    Nadarajah, Mithulananthan
    Photovoltaic (PV) panels convert a portion of the incident solar radiation into electrical energy and the remaining energy (>70 %) is mostly converted into thermal energy. This thermal energy is trapped within the panel which, in turn, increases the panel temperature and deteriorates the power output as well as electrical efficiency. To obtain high-efficiency solar photovoltaics, effective thermal management systems is of utmost. This article presents a comprehensive review that explores recent research related to thermal management solutions as applied to photovoltaic technology. The study aims at presenting a wide range of proposed solutions and alternatives in terms of design approaches and concepts, operational methods and other techniques for performance enhancement, with commentary on their associated challenges and opportunities. Both active and passive thermal management solutions are presented, which are classified and discussed in detail, along with results from a breadth of experimental efforts into photovoltaic panel performance improvements. Approaches relying on radiative, as well as convective heat transfer principles using air, water, heat pipes, phase change materials and/or nanoparticle suspensions (nanofluids) as heat-exchange media, are discussed while including summaries of their unique features, advantages, disadvantages and possible applications. In particular, hybrid photovoltaic-thermal (PV-T) collectors that use a coolant to capture waste heat from the photovoltaic panels in order to deliver an additional useful thermal output are also reviewed, and it is noted that this technology has a promising potential in terms of delivering high-efficiency solar energy conversion. The article can act as a guide to the research community, developers, manufacturers, industrialists and policymakers in the design, manufacture, application and possible promotion of high-performance photovoltaic-based technologies and systems.
  • Placeholder Image
    Publication
    Solar photovoltaic panels with finned phase change material heat sinks
    (01-05-2020)
    Singh, Preeti
    ;
    Khanna, Sourav
    ;
    Newar, Sanjeev
    ;
    Sharma, Vashi
    ;
    ;
    Mallick, Tapas K.
    ;
    Becerra, Victor
    ;
    Radulovic, Jovana
    ;
    Hutchinson, David
    ;
    Khusainov, Rinat
    Phase change material (PCM) based passive cooling of photovoltaics (PV) can be highly productive due to high latent heat capacity. However, the low rate of heat transfer limits its usefulness. Thus, the presented work aims at the improvement in PV cooling by using finned PCM (FPCM) heat sinks. In the present study, PCM heat sink and FPCM heat sinks were investigated numerically for PV cooling and the extracted heat is used for space heating. 4 kWp PV, PV-PCM and PV-FPCM systems were studied under the weather conditions of Southeast of England. It was observed that the PCM heat sinks can drop the peak PV temperature by 13 K, whereas FPCM heat sinks can enhance the PV cooling by 19 K. The PCM heat sinks can increase the PV electrical efficiency from 13% to 14%. Moreover, the daily electricity generation can be boosted by 7% using PCM and 8% by using FPCM heat sinks. In addition, 7 kWh of thermal output was achieved using the FPCM heat sink, and the overall efficiency of system increased from 13% to 19%.