Comparative performance assessment of solar dish assisted s-CO2 Brayton cycle using nanofluids

•PDSC with cavity receiver is modelled and simulated using nanofluids.•Heat produced by collector drives s-CO2 Brayton cycle to generate power.•Characteristics of solar assisted s-CO2 Brayton cycle are assessed.•Al2O3/oil shows highest overall energy, 33.73% and exergy efficiency, 36.27%.•Energy eff...

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Bibliographic Details
Published in:Applied thermal engineering 2019-02, Vol.148, p.295-306
Main Authors: Khan, Muhammad Sajid, Abid, Muhammad, Ali, Hafiz Muhammad, Amber, Khuram Pervez, Bashir, Muhammad Anser, Javed, Samina
Format: Article
Language:English
Subjects:
Aluminum oxide
Brayton cycle
Carbon dioxide
Cavity receiver
Comparative analysis
Compressing
Convective heat transfer
Energy
Exergy
Fluids
Heat transfer coefficients
Inlet temperature
Integrated system
Mass flow rate
Nanofluids
Nanoparticles
Overall exergy efficiency
Parabolic dish
Parameters
Performance assessment
Pressure ratio
Solar collectors
Solar radiation
Temperature
Titanium dioxide
Turbines
Wind effects
Wind speed
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Summary:•PDSC with cavity receiver is modelled and simulated using nanofluids.•Heat produced by collector drives s-CO2 Brayton cycle to generate power.•Characteristics of solar assisted s-CO2 Brayton cycle are assessed.•Al2O3/oil shows highest overall energy, 33.73% and exergy efficiency, 36.27%.•Energy efficiency of PDSC with Al2O3/oil is 1.73% higher than base fluid. The recent study investigates and compares the energy and exergy performances of solar dish assisted supercritical carbon dioxide re-compression with reheat Brayton cycle. Parabolic dish solar collector with cavity receiver, working on three different thermal oil based nanofluids (Al2O3, CuO & TiO2), is integrated with supercritical carbon dioxide Brayton cycle for power production. A comprehensive thermodynamic analysis and simulations are carried out in engineering equation solver to examine the overall system performance by varying certain operating parameters. These parameters are the solar radiation intensity, wind speed, ambient and inlet temperature of the fluid, mass flow rate in the receiver tube and nano particles percentage. The results demonstrate that Al2O3 oil based nanofluid has the highest overall energy and exergy efficiencies, almost 33.73% and 36.27%, respectively, and is almost 0.27% more than TiO2/oil nanofluid and 0.91% higher than CuO/oil based nanofluid. Effect of the wind velocity on receiver efficiency is also investigated. By increasing the percentage of nano particles, convective heat transfer coefficient of the fluid in the receiver tube also increases. Turbine inlet temperature and pressure ratio is varied to investigate the thermal and exergy efficiencies of the supercritical recompression Brayton cycle.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2018.11.021