RESEARCH ARTICLE

Influence mechanism of dynamic and static liquid bridge forces on particle deposition behaviors in solar photovoltaic mirrors

  • Xueqing LIU ,
  • Xiaodong ZHAO ,
  • Luyi LU ,
  • Jianlan LI
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  • School of Energy and Power Engineering, Huazhong University of Science and Technology, Wuhan 430074, China

Received date: 18 Aug 2020

Accepted date: 30 Jan 2021

Published date: 15 Jun 2021

Copyright

2021 Higher Education Press

Abstract

Solar energy is one of the most promising forms of renewable energy for solving the energy crisis and environmental problems. Dust deposition on photovoltaic mirrors has a serious negative impact on the photoelectric conversion efficiency of solar power stations. In this paper, the influence mechanism of the dynamic and static liquid bridge forces on particle deposition behaviors on solar photovoltaic mirrors is investigated. In addition, the expression and physical meaning of the particle critical separation velocity are proposed. The research results show that the static liquid bridge force can be the primary deposition force causing dust particles to adhere to photovoltaic mirrors. However, the dynamic liquid bridge force can act as a resistance force for the particle motion process and even make dust particles roll along and finally stay on the mirror. The contact force is the primary separation force that causes dust particles to flow away from the mirror. Whether dust particles adhere to the mirror depends on the relative size of the deposition and separating forces. The particle critical separation velocity describes the relative size of the collision-rebound effect and mirror adhesion effect and is expressed in Eq. (16). These research findings can provide theoretical guidance for mirror cleaning methods in the operation process of photovoltaic mirrors.

Cite this article

Xueqing LIU , Xiaodong ZHAO , Luyi LU , Jianlan LI . Influence mechanism of dynamic and static liquid bridge forces on particle deposition behaviors in solar photovoltaic mirrors[J]. Frontiers in Energy, 2021 , 15(2) : 499 -512 . DOI: 10.1007/s11708-021-0742-3

Acknowledgments

This work was supported by the National Natural Science Foundation of China (Grant No. 51975235).
1
Mekhilef S, Saidur R, Safari A. A review on solar energy use in industries. Renewable & Sustainable Energy Reviews, 2011, 15(4): 1777–1790

DOI

2
National Renewable Energy Laboratory. Realizing a clean energy future: highlights of NREL analysis (Brochure). NREL/BR-6A20–60894, 2013

3
Wang S, Cui X. Photovoltaic will become the most important power source in the world. China Science Journal, 2020, 26: 003

4
Yaghoubi M, Niknia I, Kanaan P, Experimental study of dust deposition effect on the performances of parabolic trough collectors. In: Proceedings of 17th Solar Paces Conference, Granada, Spain, 2011

5
Şahin A D. A new formulation for solar irradiation and sunshine duration estimation. International Journal of Energy Research, 2007, 31(2): 109–118

DOI

6
Sansoni P, Fontani D, Francini F, Optical collection efficiency and orientation of a solar trough medium-power plant installed in Italy. Renewable Energy, 2011, 36(9): 2341–2347

DOI

7
Sarver T, Al-Qaraghuli A, Kazmerski L L. A comprehensive review of the impact of dust on the use of solar energy: history, investigations, results, literature, and mitigation approaches. Renewable & Sustainable Energy Reviews, 2013, 22: 698–733

DOI

8
Sayyah A, Horenstein M N, Mazumder M K. Energy yield loss caused by dust deposition on photovoltaic panels. Solar Energy, 2014, 107: 576–604

DOI

9
Erdenedavaa P, Rosato A, Adiyabat A, Model analysis of solar thermal system with the effect of dust deposition on the collectors. Energies, 2018, 11(7): 1795

DOI

10
Caron J R, Littmann B. Direct monitoring of energy lost due to soiling on first solar modules in California. IEEE Journal of Photovoltaics, 2013, 3(1): 336–340

DOI

11
Mani M, Pillai R. Impact of dust on solar photovoltaic (PV) performance: research status, challenges and recommendations. Renewable & Sustainable Energy Reviews, 2010, 14(9): 3124–3131

DOI

12
Hegazy A A. Effect of dust accumulation on solar transmittance through glass covers of plate-type collectors. Renewable Energy, 2001, 22(4): 525–540

DOI

13
Ahmed O K, Mohammed Z A. Dust effect on the performance of the hybrid PV/thermal collector. Thermal Science and Engineering Progress, 2017, 3: 114–122

DOI

14
Lu H, Zhao W. CFD prediction of dust pollution and impact on an isolated groundmounted solar photovoltaic system. Renewable Energy, 2019, 131: 829–840

DOI

15
Lu H, Lu L, Wang Y. Numerical investigation of dust pollution on a solar photovoltaic (PV) system mounted on an isolated building. Applied Energy, 2016, 180: 27–36

DOI

16
Lu H, Zhang L. Numerical study of dry deposition of monodisperse and polydisperse dust on building-mounted solar photovoltaic panels with different roof inclinations. Solar Energy, 2018, 176: 535–544

DOI

17
Khadhim I J, Mehdi I J, Muhsson I M. Periodic cleaning effect on the output power of solar panels. In: 2nd Scientific Conference, Karbala University, 2014

18
Chesnutt J, Ashkanani H, Guo B, Simulation of microscale particle interactions for optimization of an electrodynamic dust shield to clean desert dust from solar panels. Solar Energy, 2017, 155: 1197–1207

DOI

19
Liu X, Yue S, Lu L, Study on dust deposition mechanics on solar mirrors in a solar power plant. Energies, 2019, 12(23): 4550

DOI

20
Chu K W, Wang B, Xu D L, CFD-DEM simulation of the gas-solid flow in a cyclone separator. Chemical Engineering Science, 2011, 66(5): 834–847

DOI

21
Sae-Heng S, Swasdisevi T, Amornkitbamrung M. Investigation of temperature distribution and heat transfer in fluidized bed using a combined CFD-DEM model. Drying Technology, 2011, 29(6): 697–708

DOI

22
Tsuji Y, Kawaguchi T, Tanaka T. Discrete particle simulation of two-dimensional fluidized bed. Powder Technology, 1993, 77(1): 79–87

DOI

23
Xu B H, Yu A B. Numerical simulation of the gas-solid flow in a fluidized bed by combining discrete particle method with computational fluid dynamics. Chemical Engineering Science, 1997, 52(16): 2785–2809

DOI

24
Zhu R R, Zhu W B, Xing L C, DEM simulation on particle mixing in dry and wet particles spouted bed. Powder Technology, 2011, 210(1): 73–81

DOI

25
Mikami T, Kamiya H, Horio M. Numerical simulation of cohesive powder behavior in a fluidized bed. Chemical Engineering Science, 1998, 53(10): 1927–1940

DOI

26
Hotta K, Takeda K, Iinoya K. The capillary binding force of a liquid bridge. Powder Technology, 1974, 10(4–5): 231–242

DOI

27
Pitois O, Moucheront P, Chateau X. Liquid bridge between two moving spheres: an experimental study of viscosity effects. Journal of Colloid and Interface Science, 2000, 231(1): 26–31

DOI

28
Liu X, Yue S, Lu L, Study on single-particle residence time of impulse, symmetric and asymmetric coaxial impinging streams. Powder Technology, 2019, 342: 118–130

DOI

29
Behrens S H, Grier D G. The charge of glass and silica surfaces. Journal of Chemical Physics, 2001, 115(14): 6716–6721

DOI

30
Bowling R A. An analysis of particle adhesion on semiconductor surfaces. Journal of the Electrochemical Society, 1985, 132(9): 2208–2214

DOI

31
Dzyaloshinskii I E, Lifshitz E M, Pitaevskii L P. The general theory of van der Waals forces. Advances in Physics, 1961, 10(38): 165–209

DOI

32
Liu X, Yue S, Lu L, Simulations of an asymmetric gas-solid two-phase impinging stream reactor. Numerical Heat Transfer Part A, 2018, 74(2): 1032–1051

DOI

33
Zhong W Q, Xiong Y Q, Yuan Z L, DEM simulation of gas-solid flow behaviors in spout-fluid bed. Chemical Engineering Science, 2006, 61(5): 1571–1584

DOI

34
Meng G S. Research on mechanism of dust particle adhesion and removal from solar panel surface in desert area. Dissertation for the Master’s Degree. Xining: Qinghai University, 2015 (in Chinese)

35
Xu H B. Study on spouting and fluidization characteristics of wet particles. Dissertation for the Doctoral Degree. Nanjing: Southeast University, 2017 (in Chinese)

36
Qasem H, Betts T R, Müllejans H, Dust-induced shading on photovoltaic modules. Progress in Photovoltaics: Research and Applications, 2014, 22(2): 218–226

DOI

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