Numerical analysis of cavity receiver with parallel tubes for cross-linear concentrated solar system

A comprehensive study to understand important parameters that affects the Cavity Linear Receiver (CLR) performance has been done. In this paper, the combined optical and thermal analysis has been successfully utilized, to investigate the thermal-hydraulic behavior of CLR of cross-linear CSP (CL-CSP)...

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Bibliographic Details
Published in:Energy (Oxford) 2021-04, Vol.220, p.119609, Article 119609
Main Authors: Mishra, Prashant, Pandey, Mukesh, Tamaura, Yutaka, Tiwari, Sumit
Format: Article
Language:English
Subjects:
Cavity linear receiver
CFD simulation
Concentrated solar power
Cross-linear concentrating solar power
Flow rates
Linear receivers
Mass flow rate
Mathematical models
Model testing
Nonuniformity
Numerical analysis
Numerical models
Optical properties
Parameters
Solar flux
Solar power
Solar system
Surface properties
Technology
Temperature
Thermal analysis
Thermal simulation
Thermodynamic efficiency
Tubes
Working conditions
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Summary:A comprehensive study to understand important parameters that affects the Cavity Linear Receiver (CLR) performance has been done. In this paper, the combined optical and thermal analysis has been successfully utilized, to investigate the thermal-hydraulic behavior of CLR of cross-linear CSP (CL-CSP) system, which is developed at the Tokyo Institute of Technology proposed a new CSP technology, which is called Cross Linear Concentrating Solar Power (CL-CSP). The first demonstration plant of cross-linear concept has been installed at Rajiv Gandhi Proudyogiki Vishwavidyalaya, Bhopal (23.2599° N, 77.4126° E), the combined analysis was done using a numerical model, which has been validated with literature and experimental test. The numerical model simulates the thermal-hydraulic behavior of CLR with the variation of working condition, surface property, and geometry. The optical efficiency and thermal efficiency are the main performance parameters for the simulation. From the numerical study, distribution of both solar flux and temperature on the receiver tubes shows high non-uniformity in axial and radial direction. Furthermore, the parameters effect on the CLR performance is investigated under general working condition of receiver of 673 K temperature, 0.0925 kg/s mass flow rate, and during solar noon of summer solstice. •The combined optical and thermal analysis has been successfully utilized.•The thermal-hydraulic behavior of CLR of cross-linear CSP system has been explored.•The geometrical effect on the CLR performance has been analyzed.•The cavity surface reflectivity affects the optical efficiency has been explored.
ISSN:0360-5442
1873-6785
DOI:10.1016/j.energy.2020.119609