Detailed performance analysis of parabolic trough collectors including geometric effect

Authors

  • M.M. Kasem Aerospace Engineering Department, Cairo University, Giza 12613, Egypt

DOI:

https://doi.org/10.15282/jmes.17.3.2023.2.0756

Keywords:

Parabolic trough collector, Thermal fluid, Performance analysis, Geometric effect, Inlet condition effect, Level curves

Abstract

Parabolic trough collectors (PTCs) have been known for years as one of the leading methods for extracting energy from the sun. In the present work, the performance of PTCs was investigated. However, its performance needs some improvement to be integrated in more and wide range of applications. This idea motivated the author to investigate the performance of parabolic trough collectors in detail. Thus, in the present work, the performance of parabolic trough collectors is investigated. The effect of eight geometric and inlet variables on the PTC performance was evaluated. Two performance factors , the temperature difference and thermal efficiency, were selected. The effect of inlet condition, including inlet mass flow rate and inlet flow temperature reflector geometry, including reflector length and width,receiver diameters, including inlet and outlet reciever diameters, and cover diameters, including the inlet and outlet cover diameters on these PFs was assessed. Eight thermal working fluids were considered. A non-linear mathematical model was developed for PTC and implemented into MATLAB code where an iterative technique was used to conduct the present analyses. Level curves were generated to study the PTC key performance parameters. The curves revealed that the maximum values of the PFs and maximum range of change in these PFs occurred when the inlet conditions were varied. Changes in the inlet temperature, and changes in the reflector geometry yielded the highest and second-highest values. The cover geometry had the minimum effect on the PFs. Moreover, the best maximum efficiency, best maximum temperature difference, and maximum range of efficiency change were obtained for water, air, and carbon dioxide, respectively. The effect of inlet temperature is more significant than the mass flow rate effect on the thermal efficiency, whereas this effect is reversed in case of the temperature difference, by which the mass flow rate exerts the least influence on the temperature difference.

References

H. Price et al., “Advances in parabolic trough solar power technology,” Journal of Solar Energy Engineering, vol. 124, no. 2, pp. 109–125, 2002.

E. Bellos, C. Tzivanidis, and K. A. Antonopoulos, “A detailed working fluid investigation for solar parabolic trough collectors,” Applied Thermal Engineering, vol. 114, pp. 374–386, 2017.

A. Malan and K. Ravi Kumar, “A comprehensive review on optical analysis of parabolic trough solar collector,” Sustainable Energy Technologies and Assessments, vol. 46, p. 101305, 2021.

M. M. Ibrahim and M. M. Kasem, “Numerical thermal study of heat transfer enhanced in laminar-turbulent transition flow through absorber pipe of parabolic solar trough collector system,” Frontiers in Heat and Mass Transfer, vol. 17, pp. 1-11, 2021.

W. Fuqiang, C. Ziming, T. Jianyu, Y. Yuan, S. Yong, and L. Linhua, “Progress in concentrated solar power technology with parabolic trough collector system: A comprehensive review,” Renewable and Sustainable Energy Reviews, vol. 79, pp. 1314–1328, 2017.

S. Raja Narayanan and S. Vijay, “Desalination of water using parabolic trough collector,” Materials Today: Proceedings, vol. 21, pp. 375–379, 2020.

L. S. Mendoza Castellanos, A. L. Galindo Noguera, E. I. Gutiérrez Velásquez, G. E. C. Caballero, E. E. Silva Lora, and V. R. Melian Cobas, “Mathematical modeling of a system composed of parabolic trough solar collectors integrated with a hydraulic energy storage system,” Energy, vol. 208, p. 118255, 2020.

M. A. Haghghi, Z. Mohammadi, S. M. Pesteei, A. Chitsaz, and K. Parham, “Exergoeconomic evaluation of a system driven by parabolic trough solar collectors for combined cooling, heating, and power generation; A case study,” Energy, vol. 192, p. 116594, 2020.

Y. Bi, L. Qin, J. Guo, H. Li, and G. Zang, “Performance analysis of solar air conditioning system based on the independent-developed solar parabolic trough collector,” Energy, vol. 196, p. 117075, 2020.

P. K. Ktistis, R. A. Agathokleous, and S. A. Kalogirou, “Experimental performance of a parabolic trough collector system for an industrial process heat application,” Energy, vol. 215, p. 119288, 2021.

İ. H. Yılmaz andA. Mwesigye, “Modeling, simulation and performance analysis of parabolic trough solar collectors: A comprehensive review,” Applied Energy, vol. 225, pp. 135–174, 2018.

B. Zou, Y. Jiang, Y. Yao, and H. Yang, “Impacts of non-ideal optical factors on the performance of parabolic trough solar collectors,” Energy, vol. 183, pp. 1150–1165, 2019.

S. A. Kalogirou, “A detailed thermal model of a parabolic trough collector receiver,” Energy, vol. 48, no. 1, pp. 298–306, 2012.

T. Fasquelle, Q. Falcoz, P. Neveu, F. Lecat, and G. Flamant, “A thermal model to predict the dynamic performances of parabolic trough lines,” Energy, vol. 141, pp. 1187–1203, 2017.

M. M. Heyhat, M. Valizade, Sh. Abdolahzade, and M. Maerefat, “Thermal efficiency enhancement of direct absorption parabolic trough solar collector (DAPTSC) by using Nanofluid and metal foam,” Energy, vol. 192, p. 116662, 2020.

D. Lei, X. Fu, Y. Ren, F. Yao, and Z. Wang, “Temperature and thermal stress analysis of parabolic trough receivers,” Renewable Energy, vol. 136, pp. 403–413, 2019.

R. V. Padilla, G. Demirkaya, D. Y. Goswami, E. Stefanakos, and M. M. Rahman, “Heat transfer analysis of parabolic trough solar receiver,” Applied Energy, vol. 88, no. 12, pp. 5097–5110, 2011.

J. Jin, Y. Ling, and Y. Hao, “Similarity analysis of parabolic-trough solar collectors,” Applied Energy, vol. 204, pp. 958–965, 2017.

B. Zou, Y. Yao, Y. Jiang, and H. Yang, “A new algorithm for obtaining the critical tube diameter and intercept factor of parabolic trough solar collectors,” Energy, vol. 150, pp. 451–467, 2018.

G. A. Salazar, N. Fraidenraich, C. A. A. de Oliveira, O. de Castro Vilela, M. Hongn, andJ. M. Gordon, “Analytic modeling of parabolic trough solar thermal power plants,” Energy, vol. 138, pp. 1148–1156, 2017.

H. Liang, S. You, and H. Zhang, “Comparison of different heat transfer models for parabolic trough solar collectors,” Applied Energy, vol. 148, pp. 105–114, 2015.

M. Fan, H. Liang, S. You, H. Zhang, W. Zheng, and J. Xia, “Heat transfer analysis of a new volumetric based receiver for parabolic trough solar collector,” Energy, vol. 142, pp. 920–931, 2018.

A. Yadav and M. Kumar, “Experimental study and analysis of parabolic trough collector with various reflectors,” International Journal of Energy and Power Engineering, vol. 7, no. 12, p. 5, 2013.

S. M. Sadegh Hosseini and M. S. Dehaj, “An experimental study on energetic performance evaluation of a parabolic trough solar collector operating with Al2O3/water and GO/water Nanofluids,” Energy, vol. 234, p. 121317, 2021.

Z. D. Cheng, Y. L. He, F. Q. Cui, B. C. Du, Z. J. Zheng, and Y. Xu, “Comparative and sensitive analysis for parabolic trough solar collectors with a detailed Monte Carlo ray-tracing optical model,” Applied Energy, vol. 115, pp. 559–572, 2014.

W. Yuanjing, Z. Cheng, Z. Yanping, and H. Xiaohong, “Performance analysis of an improved 30MW parabolic trough solar thermal power plant,” Energy, vol. 213, p. 118862, 2020.

R. V. Padilla, A. Fontalvo, G. Demirkaya, A. Martinez, and A. G. Quiroga, “Exergy analysis of parabolic trough solar receiver,” Applied Thermal Engineering, vol. 67, no. 1–2, pp. 579–586, 2014.

J. D. Osorio and A. Rivera-Alvarez, “Performance analysis of parabolic trough collectors with double glass envelope,” Renewable Energy, vol. 130, pp. 1092–1107, 2019.

A. A. Ghoneim and A. M. Mohammedein, “Parabolic trough collector performance in a hot climate,” Journal of Energy Engineering, vol. 142, no. 1, p. 04015008, 2016.

H. Yang, Q. Wang, J. Cao, G. Pei, and J. Li, “Potential of performance improvement of concentrated solar power plants by optimizing the parabolic trough receiver,” Frontier in Energy, vol. 14, no. 4, pp. 867–881, 2020.

M. M. Kasem, “Multiobjective design optimization of parabolic trough collectors,” Scientific Reports, vol. 12, p. 19964, 2022.

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Published

2023-09-27

How to Cite

[1]
M. A. M. Kasem, “Detailed performance analysis of parabolic trough collectors including geometric effect”, J. Mech. Eng. Sci., pp. 9552–9563, Sep. 2023.

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