Print Email Facebook Twitter Phase Change Materials for thermal management of PV modules Title Phase Change Materials for thermal management of PV modules Author van Nierop y Sanchez, Chris (TU Delft Electrical Engineering, Mathematics and Computer Science) Contributor Isabella, O. (mentor) Ortiz Lizcano, J.C. (mentor) Zeman, M. (graduation committee) Luscuere, P.G. (graduation committee) Degree granting institution Delft University of Technology Programme Electrical Engineering | Sustainable Energy Technology Date 2019-01-18 Abstract Whilst research in solar cell materials lead to higher efficiencies every year, new difficulties arise with every breakthrough to get an even higher efficiency. Therefore, every component of a PV system should be examined, as well as how their behaviour under operation affects performance to improve the overall PV yield. In particular the temperature of a module can have a negative impact on the power output. The drop in power output is a consequence of a negative thermal coefficient that results in a decrease of open circuit voltage with increasing temperature. For silicon solar cells, efficiency drops of 0.4-0.65%/°C have been reported in literature. Moreover, daily repetition of temperature cycles can cause mechanical degradation, thereby decreasing the lifetime of PV modules. In this thesis, phase change materials (PCM) have been studied as a method to passively reduce the operating temperature of PV modules. This is based on the ability of materials to stay at a relatively stable temperature during a phase change. By placing a PCM at the back of a PV module, the temperature difference between the module and the melting PCM causes a thermal gradient, resulting in conduction of heat away from themodule. In order to find the optimal properties of a PCM, a thermal model was first developed in COMSOL Multiphysics and benchmarked with field measurements from literature. Simulations for Rotterdam, the Netherlands, revealed that an optimized PCM could increase the yearly electrical yield by 1.23% for a rack-mounted module, or 3.52% for a roof-mounted module. Furthermore, measurements were performed with commercially available PCMs under a Large Area Solar Simulator (LASS). These were able to reduce the average module temperature by 30-36°C, albeit under heavy infrared radiation coming from the simulator. Subject Phase change materialsPhotovoltaicsThermal managementModeling To reference this document use: http://resolver.tudelft.nl/uuid:6ef7c8b7-94e7-40fd-899f-564ce2ace5a5 Embargo date 2021-01-18 Part of collection Student theses Document type master thesis Rights © 2019 Chris van Nierop y Sanchez Files PDF MSc_Thesis_civannieropysanchez.pdf 5.97 MB Close viewer /islandora/object/uuid:6ef7c8b7-94e7-40fd-899f-564ce2ace5a5/datastream/OBJ/view