Journal
ENERGY
Volume 216, Issue -, Pages -Publisher
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.energy.2020.119270
Keywords
Photovoltaic module; Absorption heat transformer; Heat upgrading; Efficiency; Power output; Sensitivity analysis
Categories
Funding
- Natural Science Foundation of Zhejiang Province [LY20E060002]
- K. C. Wong Magna Fund in Ningbo University, China
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A new hybrid system combining an absorption heat transformer with a photovoltaic module is proposed to utilize sunlight for heat upgrading. Mathematical expressions for performance indicators of the system are formulated, showing significant improvements compared to standalone photovoltaic modules. Sensitivity analyses reveal the influence of design parameters and operating conditions on system performance.
A new hybrid system coupled an absorption heat transformer to a photovoltaic module is put forward to capture the sunlight transmitted through photovoltaic module for heat upgrading. Taking account of multiple irreversible losses within the hybrid system, mathematic expressions for performance indicators of photovoltaic module, absorption heat transformer and hybrid system are formulated. Whether the proposed hybrid system is effective or not is evaluated. The maximum power output density and maximum energy efficiency of hybrid system are, respectively, enhanced by 99.05% and 99.01% compared with that of stand-alone photovoltaic module. Moreover, comprehensive sensitivity analyses are conducted to study how the hybrid system is affected by various designing parameters and operating conditions. Numerical calculation results indicate that the operating temperature of photovoltaic module, diode ideality factor, solar irradiance and various heat-transfer coefficients of absorption heat transformer have positive influence on the hybrid system performance. However, the environment temperature and heated space temperature have negative influence on the hybrid system performance. Furthermore, a practical case study has been conducted to show the performance limits of such a hybrid system. The present study may offer some new insights into the photovoltaic module performance improvement. (C) 2020 Elsevier Ltd. All rights reserved.
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