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Parameters optimization of the dust absorbing structure for photovoltaic panel cleaning robot based on orthogonal experiment method

机译:基于正交试验法的光伏面板清洁机器人吸尘结构参数优化

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摘要

Dust accumulation on the photovoltaic (PV) panels is one of the important factors that influence the PV power generation efficiency. Autonomous robot is one of the promising way to clean the PV panels effectively, in which the absorbing flow rate to a large extent determines the cleaning performance and usage effectiveness of power supply. In this paper, the air-solid two-phase flow control equations for the dust absorbing process, the mechanical behavior of the dust particles and the relationship between the pressure distribution and the dust particle velocity are analyzed theoretically for Computational Fluid Dynamics (CFD) simulation. Orthogonal experiment method is employed to optimize the structure parameters for suction inlet of PV panel cleaning robots. The suction inlet height, inlet width, outlet height, outlet width and necking radius are simplified as 16 sets of typical test optimization problem. The fluid calculation software ANSYS Fluent is adopted to execute the simulation. The optimal result is that the inlet width is 650 mm, the inlet height is 6 mm, the outlet width is 175 mm, the outlet height is 100 mm and the necking radius is 350 mm. Experiment based on the optimized structural parameters was carried out, which implies the compatibility with the simulating result. And the average wind speed at the suction inlet is 41.8 m/s, which verifies the structure optimization. (C) 2019 Elsevier Ltd. All rights reserved.
机译:光伏面板上的灰尘堆积是影响光伏发电效率的重要因素之一。自主机器人是有效清洁光伏面板的一种有前途的方法,其中吸收流量在很大程度上决定了电源的清洁性能和使用效率。本文从理论上分析了吸尘过程的气固两相流控制方程,粉尘颗粒的力学行为以及压力分布与粉尘颗粒速度之间的关系,用于计算流体动力学(CFD)模拟。 。采用正交试验法优化了光伏面板清洁机器人吸风口的结构参数。吸气入口高度,入口宽度,出口高度,出口宽度和缩颈半径简化为16组典型的测试优化问题。采用流体计算软件ANSYS Fluent进行仿真。最佳结果是入口宽度为650 mm,入口高度为6 mm,出口宽度为175 mm,出口高度为100 mm,颈缩半径为350 mm。基于优化的结构参数进行了实验,这暗示了与模拟结果的兼容性。吸风口的平均风速为41.8 m / s,验证了结构的优化。 (C)2019 Elsevier Ltd.保留所有权利。

著录项

  • 来源
    《Journal of Cleaner Production》 |2019年第20期|724-731|共8页
  • 作者单位

    Zhejiang Univ Technol, Minist Educ & Zhejiang Prov, Key Lab E&M, Hangzhou 310032, Zhejiang, Peoples R China;

    Zhejiang Univ Technol, Minist Educ & Zhejiang Prov, Key Lab E&M, Hangzhou 310032, Zhejiang, Peoples R China;

    Zhejiang Univ Technol, Minist Educ & Zhejiang Prov, Key Lab E&M, Hangzhou 310032, Zhejiang, Peoples R China;

    SIAT, CAS Key Lab Human Machine Intelligence Synergy Sy, Shenzhen 518055, Peoples R China;

    Chinese Acad Sci, Inst Automat, State Key Lab Management & Control Complex Syst, Beijing 100190, Peoples R China;

    Univ Beira Interior, Inst Telecomunicacoes, Covilha, Portugal|Natl Inst Telecommun Inatel, Santa Rita Do Sapucai, MG, Brazil;

    Univ Fortaleza UNIFOR, Fortaleza, Ceara, Brazil;

  • 收录信息
  • 原文格式 PDF
  • 正文语种 eng
  • 中图分类
  • 关键词

    Cleaning robot; Orthogonal experiment; Parameter optimization; Photovoltaics;

    机译:清洁机器人;正交实验;参数优化;光伏;

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