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A fully coupled numerical simulation of a hybrid concentrated photovoltaic/thermal system that employs a therminol VP-1 based nanofluid as a spectral beam filter
摘要: The realistic numerical modelling of multiphysics applications is an efficient way to precisely predict the operation of concentrated solar systems. Although many multiphysics conjugating approaches have been proposed in the literature, it is difficult to adopt such methods into simulating complex concentrated solar technologies. Consequently, this study introduces a novel 2D:3D numerical optical, thermal and electric coupling approach for a hybrid compound parabolic concentrator photovoltaic/thermal (CPC-PV/T) collector using a nanofluid as a spectral beam filter. In this approach, the volumetric absorbed radiation in each component of the system obtained from the non-gray 2D model is patched into the 3D model as a volumetric heat source using sophisticated computational tools. The main features of the full coupling method (FCM) are extensively analyzed and compared with the other two coupling methods previously adopted. Further, the module performance has been investigated employing both the nanofluid and base-fluid spectrum filters (BF-filter) compared with a stand-alone concentrated PV cell. From findings, the FCM can be applied to reveal more realistic operation characteristics of the proposed system compared with the other approaches, since the FCM can take into account the non-uniformity of solar illumination and the direction of reflected solar beams upon the receiver, along with the variation in the optical characteristics of utilized materials over the solar irradiance. Additionally, suspending indium tin oxide (ITO) nanoparticles into the Therminol VP1 oil raises the absorption rate over the thermal-bands with 62.5% higher than the use of BF-filter, whilst the cell temperature and the transmitted irradiance within the PV-band are obviously declined.
关键词: Radiative heat transfer,Multiphysics coupling method,Nanofluid,Concentrated photovoltaic/thermal system,Spectral beam filter
更新于2025-09-23 15:21:01
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Design and analysis of a hybrid concentrated photovoltaic thermal system integrated with an organic Rankine cycle for hydrogen production
摘要: Solar is one of the most promising energy sources because of the abundance of solar radiation in certain parts of the world. One of the main limiting factors of using traditional photovoltaic cells is that they require a lot of space to generate a significant amount of power. The alternative method, the concentrated photovoltaic (CPV) module, does not utilize the infrared part of the spectrum; thus, the concentrated photovoltaic thermal (CPVT) module was developed. In this paper, the design of a CPVT system coupling with an organic Rankine cycle (ORC) is analyzed where the CPVT thermal receiver acts as a heat exchanger in ORC to generate additional electrical power. The generated power by hybrid CPVT–ORC system is converted to hydrogen by an electrolysis system to store power. The performance of hydrogen production system using an integrated CPVT–ORC power generation system is analytically evaluated, and the results of the modeling and analyses are presented, involving assessments of the influence of varying several design parameters on the rate of hydrogen production. The CPVT and ORC together produce up to 1152 W of electricity under 160 suns solar concentration. When all the electricity is supplied to an electrolyzer, 0.1587 kg of 99.99% pure hydrogen is produced and stored for future use in a fuel cell. The electrolyzer operates at up to 57% efficiency and has an average performance of 725.5 kWh kg?1. The results revealed that coupling ORC to the CPVT enables the system to improve the electrical power generation and consequently diurnal hydrogen production increases up to 30%.
关键词: Concentrated photovoltaic thermal (CPVT),Electrolyzer,Solar energy,Hydrogen,Organic Rankine cycle (ORC)
更新于2025-09-23 15:21:01
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Experimental and theoretical analysis of hybrid concentrated photovoltaic/thermal system using parabolic trough collector
摘要: In the current work, a hybrid concentrated photovoltaic thermal system was designed and coupled with a parabolic trough collector and investigated theoretically and experimentally for combined heat and power output. In the design, a photovoltaic module was mounted on a flat surface of parabolic trough absorber tube having semi cylindrical shape. A provision was made to cool photovoltaic panel from both the surfaces by flowing water through the absorber tube as well as the annulus of between absorber tube and glass cover. The model was developed using first law of the thermodynamics and then validated using experimental data generated through the fabricated setup. During the experimentation, the annulus flow rate was varied from 0.008 kg/s, 0.017 kg/s and 0.025 kg/s and inner flow rate was varied from 0.075 kg/s, 0.083 kg/s and 0.091 kg/s. The field testing results showed the mean overall efficiency of system obtained as 61.42%, 64.61% and 66.36% for inner tube flow rate of 0.075 kg/s, 0.083 kg/s and 0.091 kg/s respectively for annulus flow rate of 0.008 kg/s. The theoretical results of hybrid system obtained from the simulation are in good agreement with the experimental data. In the end environmental cost analysis was also carried out for the proposed system.
关键词: Hybrid system,Concentrated Photovoltaic/thermal,Parabolic trough collector,Renewable energy,Solar energy
更新于2025-09-23 15:19:57