Structural Analysis Model to Evaluate the Mechanical Reliability of Large-area Photovoltaic Modules

Yo Han Noh; Jeong Ho Jeong; Jaehyeong Lee

doi:10.21218/CPR.2022.10.2.056

All Issue

2022 Vol.10, Issue 2 Preview Page Next Page

Structural Analysis Model to Evaluate the Mechanical Reliability of Large-area Photovoltaic Modules 대면적 태양광 모듈의 기계적 신뢰성 평가를 위한 모델

30 June 2022. pp. 56-61

PDF XML

Abstract

Recently, the expansion of the domestic solar market due to the promotion of eco-friendly and alternative energy-related policies is promising, and it is expected to lead the high-efficiency/high-power module market based on M10 or larger cells to reduce LCOE, 540-560W, M12 based on M10 cells Compared to the existing technology with an output of 650-700W based on cells, it is necessary to secure competitiveness through the development of modules with 600W based on M10 cells and 750W based on M12 cells. For the development of high efficiency/high-power n-type bifacial, it is necessary to secure a lightweight technology and structure due to the increase in weight of the glass to glass module according to the large area of the module. Since the mechanical strength characteristics according to the large area and high weight of the module are very important, design values such as a frame of a new structure that can withstand the mechanical load of the Mechanical Load Test and the location of the mounting hole are required. In this study, a structural analysis design model was introduced to secure mechanical reliability according to the enlargement of the module area, and the design model was verified through the mechanical load test of the actual product. It can be used as a design model to secure the mechanical reliability required for PV modules by variables such as module area, frame shape, and the location and quantity of mounting holes of the structural analysis model verified. A relationship of output drop can be obtained.

Keywords

Large-area PV Modules

High-efficiency Modules

Mechanical Reliability

Structural Analysis

Evaluation Model

References

C. H. Huang, L. D. Chih and S.J. Ho, Assessing the reliability and degradation of ribbon in photovoltaic module, PVSC IEEE 37th (2011). 10.1109/PVSC.2011.618660922384581

J. Campbell, Y. Zemen, B. Richardson and B. Striner, Photovoltaic module performance and degradation as compared in distinct climatic regions, PVSC IEEE 38th (2012). 10.1109/PVSC.2012.6317829

M. Aßmus, J. Steffen, K. A. Weiss and K. Michael, Meas urement and simulation of vibrations of PV‐modules induced by dynamic mechanical loads, Progress in photovoltaics research and applications, 19(6), p. 688 (2011). 10.1002/pip.1087

S. K. Schröder, I. Kunze, U. Eitner and M. Köntges, Spatial and orientational distribution of cracks in crystalline photovoltaic modules generated by mechanical load tests, Solar energy materials and solar cells, 95(11), p.3054 (2011). 10.1016/j.solmat.2011.06.032

M. Köntges, I. Kunze, S. K. Schröder, X. Breitnmoser and B. Bjørneklettb, The risk of power loss in crystalline silicon based photovoltaic modules due to micro-cracks, Solar energy materials and solar cells, 95(4), p. 1137 (2010). 10.1016/j.solmat.2010.10.034

J. S. Park, W. J. Oh, J. H. Joo, J. S. Yi, B. Y. Hong and J. H. Lee, Design of High-Power and High-Density Photovoltaic Modules Based on a Shingled Cell String, Journal of nanoscience and nanotechnology, 20(11), p. 6996 (2020). 10.1166/jnn.2020.1883732604548

W. J. Oh, J. S. Park, C. H. Jeong, J. H. Park, J. S. Yi and J. H. Lee, Design of a solar cell electrode for a shingled photovoltaic module application, applied surface science, 510, 145420 (2020). 10.1016/j.apsusc.2020.145420

Information

Publisher :Korea Photovoltaic Society
Publisher(Ko) :한국태양광발전학회
Journal Title :Current Photovoltaic Research
Volume : 10
No :2
Pages :56-61
Received Date : 2022-05-23
Revised Date : 2022-06-08
Accepted Date : 2022-06-13
DOI :https://doi.org/10.21218/CPR.2022.10.2.056

Current Photovoltaic Research ISSN:2288-3274(Print) 2508-125X(Online)

All Issue