Print Email Facebook Twitter Modelling the performance of photovoltaic thermal collectors Title Modelling the performance of photovoltaic thermal collectors Author Dijkstra, Jaap (TU Delft Electrical Engineering, Mathematics and Computer Science) Contributor Santbergen, R. (mentor) Ul Abdin, Z.U.A. (mentor) Isabella, O. (graduation committee) Delfos, R. (graduation committee) Degree granting institution Delft University of Technology Programme Sustainable Energy Technology Date 2024-04-25 Abstract This thesis addresses a critical challenge in the field of renewable energy, focusing on the efficient utilization of Photovoltaic-thermal (PVT) systems. Much research has already been done on PVT and there exist many thermal simulation models. However, many of the researches done and existing thermal models are restricted to a specific collector archetype which gives less flexibility in experimentation between multiple archetypes. In addition, many experimental researches require a physical setup for measurements and thermal simulation models would need to be altered for different research approaches and collector archetypes. The primary objective of this thesis project is therefore to create a performance simulation framework model that is suitable for the calculation of the thermal and electrical performance for any PVT archetype. It aims to develop and implement a toolbox application encompassing heat transfer models that can establish a foundation for future research on PVT collector optimization, PVT system integration and PVT performance analysis. This toolbox application will be implemented into the PVMD Toolbox Vogt et al. (2022), housed within the Photovoltaic Materials and Devices research group at TU Delft.Selected PVT collector: This research has visualized that there is a wide variety of PVT archetypes that can be used for current and future generations of PVT collectors. PVT collectors can be combined with heat pumps, refrigeration pumps, phase change materials and multiple forms of heat collection via fluids or air. These combinations can all contribute to high electrical and thermal efficienciesNumerical heat transfer model and assumptions: It is possible to calculate heat transfer rates of complex designs when using a Finite Element Method (FEM) approach to calculate the heat transfer within the collector. With the proper convective and radiative equations to the environment, the heat transfer inside the collector and to the environment could be calculated without needing an experimental setup. Performance calculations: The performance calculations gave insight into the simulated behavior of the PVT collector when operating in real-world conditions. Ranging the inclination angle from 0 to 60 degrees showed that the thermal efficiency became around 55% at an irradiance of 800 W/m2 at 45 degrees. It also showed that differences in dimensions like pipe thicknesses and number of pipes did not affect the thermal performance that much. The daily performance calculations illustrated that the thermal energy lost to the environment can be three times as high as the incoming solar energy due to the low ambient temperatures compared to the inflow temperature. In the summer, PVT can achieve high total efficiencies of around 75% making PVT suitable during those times. The economic analysis showed that a PVT collector can have an LCOE of $0.08/kWh which is lower than the $0.13/kWh of conventional PV. Subject PVTmodellingheat transfer To reference this document use: http://resolver.tudelft.nl/uuid:ad8fe540-28e2-4279-b6bd-338acee76bea Part of collection Student theses Document type master thesis Rights © 2024 Jaap Dijkstra Files PDF Modelling_of_PVT_collecto ... jkstra.pdf 10.69 MB Close viewer /islandora/object/uuid:ad8fe540-28e2-4279-b6bd-338acee76bea/datastream/OBJ/view