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Abstract
A comparative study was carried out incorporating a novel approach for thermal performance evaluations of commonly used parabolic trough collectors, namely the Euro, Sky, and Helio troughs. In the analysis, pressurized water and therminol-VP1 (eutectic mixture of diphenyl oxide (DPO) and biphenyl) fluid were introduced as working fluids, and the governing equation of energy was simulated for various working fluid mass flow rates and inlet temperatures. The thermal performance of the troughs was assessed by incorporating the first- and second-law efficiencies and by using temperature increases and pressure drops of the working fluid. It was found that the first-law efficiency of the troughs increased with the working fluid mass flow rate, while it decreased with an increasing working fluid inlet temperature. The first-law efficiency remained the highest for the Euro trough, followed by the Sky and Helio troughs. The second-law efficiency reduced with an increasing working fluid mass flow rate, while it increased with an increasing working fluid inlet temperature. The second-law efficiency became the highest for the Helio Trough, followed by the Sky and Euro troughs. The temperature increase remained the highest along the length of the receiver for the Helio Trough compared to that corresponding to the Euro and Sky troughs for the same mass flow rate of the working fluid. The pressure drops in the working fluid became high for the Euro Trough, followed by the Sky and Helio troughs. The pressurized water resulted in higher second-law efficiency than the therminol-VP1 fluid did for all of the troughs considered.
Highlights
The utilization of renewable energy resources has become a necessity rather than a preference due to the recent changes in the climate
Many factors affect the performance of solar troughs, some of which include the concentration of solar radiation, wind speed, working fluid type, mass flow rate, and inlet temperature of the working fluid
The firstfirst- and parabolic troughs, namely the the Trough, and andsecondsecond-law law efficiencies were formulated by adopting the configurations of troughs, the troughs, a comparativestudy efficiencies were formulated by adopting the configurations of the andand a comparative study was introduced to assess the thermal performance of each trough for various mass flow rates was introduced to assess the thermal performance of each trough for various mass flow rates and inlet and inlet temperatures of the working fluids
Summary
The utilization of renewable energy resources has become a necessity rather than a preference due to the recent changes in the climate. Many factors affect the performance of solar troughs, some of which include the concentration of solar radiation, wind speed, working fluid type, mass flow rate, and inlet temperature of the working fluid. The thermal performance of troughs and receivers in terms of first- and second-law efficiencies can be improved via the proper selection of operating conditions such as working fluid type, mass flow rate, and the inlet temperature of the working fluid. The design configurations of solar troughs and receivers are well established, the proper selection of a solar trough system to maximize its thermal performance has become critical for certain practical applications The working fluid, such as pressurized water or therminol liquid, at different mass flow rates influences the trough system performance. Thermal analysis of a trough system’s performance in terms of first and second law analysis has Energies 2019, 12, 3130; doi:10.3390/en12163130 www.mdpi.com/journal/energies
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