[1]邓淑丹,林光磊,黄登峰,等.光伏跟踪支架风荷载的确定及结构优化设计[J].福建理工大学学报,2023,21(06):558-565.[doi:10.3969/j.issn.1672-4348.2023.06.008]
 DENG Shudan,LIN Guanglei,HUANG Dengfeng,et al.Wind load determination and structuraloptimization design of photovoltaic tracking supports[J].Journal of Fujian University of Technology;,2023,21(06):558-565.[doi:10.3969/j.issn.1672-4348.2023.06.008]
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光伏跟踪支架风荷载的确定及结构优化设计()
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《福建理工大学学报》[ISSN:2097-3853/CN:35-1351/Z]

卷:
第21卷
期数:
2023年06期
页码:
558-565
栏目:
出版日期:
2023-12-25

文章信息/Info

Title:
Wind load determination and structuraloptimization design of photovoltaic tracking supports
作者:
邓淑丹林光磊黄登峰闫晓磊黄仕塔田君福
福建理工大学材料科学与工程学院
Author(s):
DENG Shudan LIN Guanglei HUANG Dengfeng2 YAN Xiaolei2 HUANG Shita TIAN Junfu
School of Materials Science and Engineering, Fujian University of Technology
关键词:
跟踪支架风荷载轻量化有限元分析HyperStudy
Keywords:
photovoltaic tracking supportswind loadlightweightfinite element analysisHyperStudy
分类号:
TM615
DOI:
10.3969/j.issn.1672-4348.2023.06.008
文献标志码:
A
摘要:
光伏支架作为太阳能光伏系统的核心支撑结构,其性能优劣决定了系统能否安全高效运维。基于计算流体动力学(CFD)原理,利用FLUENT 软件对光伏支架风场进行数值模拟,以确定光伏组件所承受的风荷载,并将计算结果与日本经验公式进行了比较验证。通过建立光伏支架的结构有限元模型,对光伏跟踪支架刚度、强度及模态进行了分析。根据分析结果,以质量最小化为目标函数、最大应力和变形为约束条件,在HyperStudy 中运用全局响应面法对跟踪支架各部件的厚度进行优化设计。结果表明:在保证结构性能指标的基础上,光伏跟踪支架减重70 kg、轻量化减重率达19.4 %。
Abstract:
As the core support structure of solar photovoltaic systems, the performance of photovoltaic brackets determines the safe and efficient operation and maintenance of the system. Based on the principle of computational fluid dynamics (CFD), the wind field of photovoltaic support was numerically simulated using FLUENT software to determine the wind load of photovoltaic modules. The calculation results were compared with Japanese empirical formulas for verification. The structural finite element model of photovoltaic support was established, and the stiffness, strength and modal analysis of photovoltaic tracking support were conducted. Based on the analysis results, with mass minimization as the objective function, and maximum stress and deformation as the constraints,the global response surface method was used to optimize the design of the thickness of each component of the photovoltaic tracking support in HyperStudy. Results indicate that on the basis of ensuring the structural performance indicators, the goal of reducing the weight of the photovoltaic tracking bracket by 70 kg and a lightweight weight reduction rate of 19.4% has been achieved.

参考文献/References:

[1] 中华人民共和国建设部,国家质量监督检验检疫总局. 建筑结构荷载规范:GB 50009—2001[S]. 北京:中国建筑工业出版社,2002. [2] 中华人民共和国住房和城乡建设部. 光伏发电站设计规范:GB 50797—2012[S]. 北京:中国计划出版社,2012. [3] Minimum Design Loads for Buildings and Other Structures:ASCE 7-98[S]. American Society of Civil Engineers,2006. [4] 光伏天线阵结构的负载设计指南:JIS C 8955:2017[S]. 日本工业标准调查会,2017.[5] Eurocode 1:Actions on structures - Part 1-4:General actionsWind actions:DS/EN 1991-1-4:2007[S]. Danish Standards,2007. [6] LEE G H,CHOI J W,KIM J,et al. Numerical simulations of wind loading on the floating photovoltaic systems[J]. Journal of Visualization,2021,24(3):471-484. [7] HE X H,DING H,JING H Q,et al. Mechanical characteristics of a new type of cable-supported photovoltaic module system[J]. Solar Energy,2021,226:408-420. [8] MA WY,ZHANG W D,ZHANG X B,et al. Experimental investigations on the wind load interference effects of single-axis solar tracker arrays[J]. Renewable Energy,2023,202:566-580. [9] TANG Z,ZENG Y W,HUANG H,et al. Structural design and simulation analysis of new photovoltaic bracket for temporary substation[J]. Integrated Ferroelectrics,2023,233(1):67-80. [10] 张亮,朱紫玲,罗冰冰,等. 固定式光伏支架可承受荷载有限元分析[J]. 太阳能学报,2022,43(9):15-20. [11] 董小虎,王士涛,周德淳. 光伏跟踪支架檩条结构高刚性轻量化设计[J]. 中国机械工程,2023,34(10):1207-1213. [12] 汪纯鹏. 76m~2太阳光伏系统支架结构的力学分析与设计优化[D]. 长春:吉林大学,2016. [13] 张汉中,孟文俊. 光伏组件结构最优设计方案的模拟研究[J]. 太阳能,2022(8):27-36. [14] 秦伟康. 球团焙烧用大尺寸固定筛的动静力学分析及结构优化[D]. 镇江:江苏大学,2022. [15] CABAN J,NIEOCZYM A,GARDYNSKI L. Strength analysis of a container semi-truck frame[J]. Engineering Failure Analysis,2021,127:105487. [16] ZHUANG WM,SHI H D,XIE D X,et al. Research on the lightweight design of body-side structure based on crashworthiness requirements[J]. Journal of Shanghai Jiaotong University (Science),2019,24(3):313-322. [17] 刘晓宇,袁彬,戴太阳,等. 基于自适应网格及响应面模型的永磁电机多目标优化[J]. 微特电机,2020,48(7):24-27,30.

更新日期/Last Update: 2023-12-25