Performance analysis of receiver of parabolic trough solar collector: Effect of selective coating, vacuum and semitransparent glass cover

Ray, Subhankar; Tripathy, Arun Kumar; Sahoo, Sudhansu S.; Bindra, Hitesh

doi:10.1002/er.4137

Cited by 17 publications

(9 citation statements)

References 17 publications

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“…Different Re numbers, different receiver diameters, and different fluid inlet temperatures have been considered to study their effect on the secondary flow. Ray et al preformed numerical 3D simulations considering the glass envelope as semi‐transparent and modeling the selective coating on the outer surface of the solar absorber with a range of DNI (750‐1000 W/m 2 ) and different mass flow rate of the working fluid (1.7‐17.6 kg/s). Results showed that the temperature difference in the circumferential direction decreased by 71.95% with increasing the mass flow rate from 1.7 to 17.6 kg/s and the thermal efficiency has been affected slightly with increasing the DNI as well as mass flow rate.…”

Section: Literature Review Of Ptcsmentioning

confidence: 99%

An extensive review of various technologies for enhancing the thermal and optical performances of parabolic trough collectors

Abed

Afgan

2020

Int J Energy Res

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A wide range of engineering industrial applications require both the thermal and optical efficiencies of the system to be maximized with a reasonable low penalty for the friction factor and subsequently low losses in pressure. Among the family of concentrated solar power systems, parabolic trough collectors (PTCs), which have recently received significant attention, face similar challenges. The current work presents an extensive review of the PTC systems comparing recent and past technologies, which are widely being used to improve and enhance the thermal and optical efficiencies. Furthermore, the techniques used for single and two-phase flow modeling in numerical simulations, design variables, and experimental processes have been discussed in detail. The article also presents different numerical methods and analytical approaches of implementing the nonuniform solar distribution with different design parameters. Four main technologies are comprehensively addressed to effectively enhance the thermal performance of the PTCs; changing working heat transfer fluids, replacing the working fluids by nanofluids (single and hybrid) that have higher thermal-physical properties than those of base working fluids, inserting different tabulators with various design configurations, and finally combining the advantages of nanofluids and swirl generators in the same application. The article also critically summarizes the studies investigating the enhancement of thermal performance: use of novel design of PTCs and passive heat transfer enhancement techniques. Finally, a wide range of numerical and experimental studies are proposed for the future work related to the aforementioned main technologies. K E Y W O R D Sheat transfer enhancements, nanofluids, parabolic trough solar collectors, solar thermal energy, tabulators, thermal and optical performances

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Section: Literature Review Of Ptcsmentioning

confidence: 99%

An extensive review of various technologies for enhancing the thermal and optical performances of parabolic trough collectors

Abed

Afgan

2020

Int J Energy Res

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“…In the study, the heat transfer fluid of Al2O3 nanofluid 4% revealed the best collector efficiency. Ray et al [10] conducted a numerical analysis of selective coatings on the absorber tube. The thermal efficiency can be increased up to 34.6% by the selective coating.…”

Section: Introductionmentioning

confidence: 99%

One-Dimensional Modeling of Triple-Pass Concentric Tube Heat Exchanger in the Parabolic Trough Solar Air Collector

Phu¹,

Ngo²

2022

Heat Exchangers

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The parabolic trough solar collector has a very high absorber tube temperature due to the concentration of solar radiation. The high temperature leads to large heat loss to the environment which reduces efficiency of the parabolic trough collector. The heat loss reduction can be obtained by adopting a multi-pass fluid flow arrangement. In this chapter, airflow travels in three passes of the receiver to absorb heat from the glass covers and absorber tube to decrease surface temperatures. 1D mathematical model is developed to evaluate effective efficiency and the temperature distribution of surfaces and fluid. The mathematical modeling is based on air temperature gradients and solved by a numerical integration. Diameter ratios of outer glass to inner glass (r23) and inner glass to absorber tube (r12), Reynolds number (Re), and tube length (L) are varied to examine the efficiency and the temperature distribution. Results showed that the highest efficiency is archived at r23 = 1.55 and r12 in the range of 1.45 to 1.5. The efficiency increases with Re and decreases with L due to dominant heat transfer in terms of thermohydraulic behavior of a concentrating solar collector. With the optimum ratios, absorber tube temperature can reduce 15 K compared with another case.

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“…In contrast, the attempts to restrict the heat loss and improve the absorber tube behaviour highlighted improvement by 30-35% [2]. Similar researches have aimed at improvements of absorber tube behaviour with selective coatings.…”

Section: Introductionmentioning

confidence: 99%

Experimental study of epoxy based graphite coating on parabolic trough solar collector

Nagaraj

2022

J. Phys.: Conf. Ser.

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Parabolic Trough Solar Collector is a line concentration method employed to harness solar energy for high-temperature applications. Attempts are made to improve the heat transfer of PTSC by reducing convectional losses of the absorber tube by using covering on the absorber tube. The study attempts to improve the Parabolic Trough Solar Collector performance using epoxy-based graphite coating through experimentation. The experiment is attempted for varied flow rates of 0.3, 0.7 and 1.1 litres per minute. The study highlighted that the coating method improved the rise in thermal fluid temperature over the absorber tube covering method by 24%. The improvement in heat transfer due to the graphite coating can be accounted for by the improvement in absorptivity and insulation, leading to better heat transfer to the thermal fluid utilized in the absorber tube.

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Performance analysis of receiver of parabolic trough solar collector: Effect of selective coating, vacuum and semitransparent glass cover

Cited by 17 publications

References 17 publications

An extensive review of various technologies for enhancing the thermal and optical performances of parabolic trough collectors

An extensive review of various technologies for enhancing the thermal and optical performances of parabolic trough collectors

One-Dimensional Modeling of Triple-Pass Concentric Tube Heat Exchanger in the Parabolic Trough Solar Air Collector

Experimental study of epoxy based graphite coating on parabolic trough solar collector

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