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Receiver with light-trapping nanostructured coating: A possible way to achieve high-efficiency solar thermal conversion for the next-generation concentrating solar power

Author

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  • Wang, Wen-Qi
  • Li, Ming-Jia
  • Jiang, Rui
  • Hu, Yi-Huang
  • He, Ya-Ling

Abstract

To improve the receiver's solar-thermal conversion efficiency at high temperature for the next-generation concentrating solar power (CSP), a receiver with the light-trapping nanostructured coating is proposed herein. However, for the CSP plant with the light-trapping nanostructure coated receiver, the scale of the heliostat field is on the order of meters (∼10m), the solar receiver tube on the order of millimeters (∼10 mm), and the light-trapping coating on the order of nanometers (∼100 nm). The whole system spans nine orders of magnitude, which makes it extremely complicated and difficult to evaluate the receiver's optical and thermal performance. To solve this problem, a multi-scale model is proposed by combining Monte Carol Ray tracing method (MCRT), finite difference time domain (FDTD) method, and finite volume method (FVM). Then, the influences of three typical light-trapping nanostructured coatings, including pyramid nanostructure, moth-eye nanostructure, and cone nanostructure, on the receiver's optical-thermal performance are studied. Among these three typical nanostructures, the cone nanostructure can maximize the receiver's optical-thermal performance, with a receiver efficiency more than 88%, which is higher than that of the commercial Pyromark2500 coating by 6–10% points. The study demonstrates that the receiver with light-trapping nanostructured coatings can achieve high receiver efficiency for the next-generation CSP.

Suggested Citation

  • Wang, Wen-Qi & Li, Ming-Jia & Jiang, Rui & Hu, Yi-Huang & He, Ya-Ling, 2022. "Receiver with light-trapping nanostructured coating: A possible way to achieve high-efficiency solar thermal conversion for the next-generation concentrating solar power," Renewable Energy, Elsevier, vol. 185(C), pages 159-171.
    • Handle: RePEc:eee:renene:v:185:y:2022:i:c:p:159-171
    DOI: 10.1016/j.renene.2021.12.026
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    as
    1. Joeri Rogelj & Daniel Huppmann & Volker Krey & Keywan Riahi & Leon Clarke & Matthew Gidden & Zebedee Nicholls & Malte Meinshausen, 2019. "A new scenario logic for the Paris Agreement long-term temperature goal," Nature, Nature, vol. 573(7774), pages 357-363, September.
    2. Kevin A. Arpin & Mark D. Losego & Andrew N. Cloud & Hailong Ning & Justin Mallek & Nicholas P. Sergeant & Linxiao Zhu & Zongfu Yu & Berç Kalanyan & Gregory N. Parsons & Gregory S. Girolami & John R. A, 2013. "Three-dimensional self-assembled photonic crystals with high temperature stability for thermal emission modification," Nature Communications, Nature, vol. 4(1), pages 1-8, December.
    3. Smriti Mallapaty, 2020. "How China could be carbon neutral by mid-century," Nature, Nature, vol. 586(7830), pages 482-483, October.
    4. He, Ya-Ling & Zhou, Yi-Peng & Hu, Yi-huang & Hung, Tzu-Chen, 2020. "A multiscale-multiphysics integrated model to investigate the coupling effects of non-uniform illumination on concentrated photovoltaic system with nanostructured front surface," Applied Energy, Elsevier, vol. 257(C).
    5. He, Ya-Ling & Qiu, Yu & Wang, Kun & Yuan, Fan & Wang, Wen-Qi & Li, Ming-Jia & Guo, Jia-Qi, 2020. "Perspective of concentrating solar power," Energy, Elsevier, vol. 198(C).
    6. M. Caccia & M. Tabandeh-Khorshid & G. Itskos & A. R. Strayer & A. S. Caldwell & S. Pidaparti & S. Singnisai & A. D. Rohskopf & A. M. Schroeder & D. Jarrahbashi & T. Kang & S. Sahoo & N. R. Kadasala & , 2018. "Ceramic–metal composites for heat exchangers in concentrated solar power plants," Nature, Nature, vol. 562(7727), pages 406-409, October.
    7. Dan, Atasi & Barshilia, Harish C. & Chattopadhyay, Kamanio & Basu, Bikramjit, 2017. "Solar energy absorption mediated by surface plasma polaritons in spectrally selective dielectric-metal-dielectric coatings: A critical review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 79(C), pages 1050-1077.
    8. Wang, Kun & He, Ya-Ling & Zhu, Han-Hui, 2017. "Integration between supercritical CO2 Brayton cycles and molten salt solar power towers: A review and a comprehensive comparison of different cycle layouts," Applied Energy, Elsevier, vol. 195(C), pages 819-836.
    9. Ho, Clifford K. & Iverson, Brian D., 2014. "Review of high-temperature central receiver designs for concentrating solar power," Renewable and Sustainable Energy Reviews, Elsevier, vol. 29(C), pages 835-846.
    10. Wang, Wen-Qi & Qiu, Yu & Li, Ming-Jia & He, Ya-Ling & Cheng, Ze-Dong, 2020. "Coupled optical and thermal performance of a fin-like molten salt receiver for the next-generation solar power tower," Applied Energy, Elsevier, vol. 272(C).
    11. He, Ya-Ling & Xiao, Jie & Cheng, Ze-Dong & Tao, Yu-Bing, 2011. "A MCRT and FVM coupled simulation method for energy conversion process in parabolic trough solar collector," Renewable Energy, Elsevier, vol. 36(3), pages 976-985.
    12. Qiu, Yu & He, Ya-Ling & Li, Peiwen & Du, Bao-Cun, 2017. "A comprehensive model for analysis of real-time optical performance of a solar power tower with a multi-tube cavity receiver," Applied Energy, Elsevier, vol. 185(P1), pages 589-603.
    13. J. G. Fleming & S. Y. Lin & I. El-Kady & R. Biswas & K. M. Ho, 2002. "All-metallic three-dimensional photonic crystals with a large infrared bandgap," Nature, Nature, vol. 417(6884), pages 52-55, May.
    14. Wang, Wen-Qi & Li, Ming-Jia & Cheng, Ze-Dong & Li, Dong & Liu, Zhan-Bin, 2021. "Coupled optical-thermal-stress characteristics of a multi-tube external molten salt receiver for the next generation concentrating solar power," Energy, Elsevier, vol. 233(C).
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    1. Wang, Wen-Qi & He, Ya-Ling & Jiang, Rui, 2022. "A multi-scale solar receiver with peak receiver efficiency over 90% at 720 °C for the next-generation solar power tower," Renewable Energy, Elsevier, vol. 200(C), pages 714-723.
    2. Yifan Guo & Kaoru Tsuda & Sahar Hosseini & Yasushi Murakami & Antonio Tricoli & Joe Coventry & Wojciech Lipiński & Juan F. Torres, 2024. "Scalable nano-architecture for stable near-blackbody solar absorption at high temperatures," Nature Communications, Nature, vol. 15(1), pages 1-13, December.
    3. Ye, Kai & Li, Qing & Zhang, Yuanting & Qiu, Yu & Liu, Bin, 2022. "An efficient receiver tube enhanced by a solar transparent aerogel for solar power tower," Energy, Elsevier, vol. 261(PB).

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