铜铟镓硒薄膜光伏组件中电池与封装材料界面的光学特性对组件性能的影响

林舒平; 单洪青; 庄大明

doi:10.37188/fgxb20204107.0849

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铜铟镓硒薄膜光伏组件中电池与封装材料界面的光学特性对组件性能的影响

器件制备及器件物理 | 更新时间：2020-09-10

- 铜铟镓硒薄膜光伏组件中电池与封装材料界面的光学特性对组件性能的影响
- Influence of Cell/Encapsulation Material Interface Optical Properties on Cu(InGa)Se₂ Solar Module Performance
- 发光学报 2020年41卷第7期页码：849-857
- 作者机构：
  
  1.北京低碳清洁能源研究院, 北京 102211
  2.神华(北京)光伏科技研发有限公司, 北京 102211
  3.清华大学材料科学与工程学院, 北京 100084
- 作者简介：
  
  [ "林舒平(1987－), 男, 江西上饶人, 博士, 博士后, 2017年于南开大学获得博士学位, 主要从事铜铟镓硒薄膜太阳电池及其光伏组件的研究。E-mail:linshuping1987@126.com" ]
- 基金信息：
  
  国家重点研发计划(2018YFB1500200)
- DOI：10.37188/fgxb20204107.0849
  中图分类号：
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林舒平, 单洪青, 庄大明. 铜铟镓硒薄膜光伏组件中电池与封装材料界面的光学特性对组件性能的影响[J]. 发光学报, 2020,41(7):849-857.

Shu-ping LIN, Hong-qing SHAN, Da-ming ZHUANG. Influence of Cell/Encapsulation Material Interface Optical Properties on Cu(InGa)Se₂ Solar Module Performance[J]. Chinese Journal of Luminescence, 2020,41(7):849-857.
林舒平, 单洪青, 庄大明. 铜铟镓硒薄膜光伏组件中电池与封装材料界面的光学特性对组件性能的影响[J]. 发光学报, 2020,41(7):849-857. DOI： 10.37188/fgxb20204107.0849.

Shu-ping LIN, Hong-qing SHAN, Da-ming ZHUANG. Influence of Cell/Encapsulation Material Interface Optical Properties on Cu(InGa)Se₂ Solar Module Performance[J]. Chinese Journal of Luminescence, 2020,41(7):849-857. DOI： 10.37188/fgxb20204107.0849.

摘要

根据测试数据，分析模拟了铜铟镓硒（CIGS）薄膜光伏组件中电池的活性区域、非活性区域与封装材料之间界面的光学特性对组件的短路电流产生的影响。根据组件结构建立了光学模型，从光学模拟结果分析组件内的反射与吸收。发现电池前电极透明导电氧化物薄膜（TCO）与封装材料界面的反射不可忽视，提出通过在透明导电氧化物薄膜与封装材料之间添加减反射层，并以MgO作为膜层材料以降低活性区域的界面反射；模拟了在非活性区域一次反射光角度与二次反射的关系，由此分析了非活性区域反射面倾角、镜面反射与漫反射比例对光利用的影响。模拟结果显示，活性区域的减反层结构可降低透明导电氧化物薄膜表面的反射率1%以上，而通过在非活性面积区域制备光反射结构，理论上能够利用非活性区域光照超过50%。

Abstract

The influence of cell/encapsulant interface optical properties of active and non-active areas on Cu(InGa)Se,2, PV module short-circuit current was studied by simulation based on measurement data. The absorption and reflection inside the module were analyzed according to the simulation of models established based on Cu(InGa)Se,2, module structure. It reveals that the reflection of TCO/encapsulant interface is not negligible in active area. So, MgO as the anti-reflection coating is proposed. The relation between first reflection angle and the second reflectivity was simulated in non-active area. Based on this, the influences of reflector inclination and the ratio of specular/diffuse reflection on light utilization were analyzed. The simulation results show that the MgO anti-reflection coating in active area reduces the interface reflection for over 1% and the light in non-active area could be utilized for over 50% by preparing reflection structure in non-active area, theoretically.

关键词

铜铟镓硒薄膜光伏组件模拟界面反射光管理

Keywords

Cu (In Ga) Se2 thin film solar modulesimulationinterface reflectionlight management

references

GREEN M A, DUNLOP E D, HOHL-EBINGER J, et al.. Solar cell efficiency tables(version 55)[J].Prog. Photovolt.:Res. Appl., 2020, 28(1):3-15.

HUTCHINS M. Nice Solar Energy sets new world record for CIGS efficiency[EB/OL]. (2019-12-04)[2020-04-19].https://www.pv-magazine.com/2019/12/04/nice-solar-energy-sets-new-world-record-for-cigs-efficiency/https://www.pv-magazine.com/2019/12/04/nice-solar-energy-sets-new-world-record-for-cigs-efficiency/.

MCINTOSH K R, COTSELL J N, CUMPSTON J S, et al.. An optical comparison of silicone and EVA encapsulants for conventional silicon PV modules: a ray-tracing study[C].Proceedings of The 2009 34th IEEE Photovoltaic Specialists Conference, Philadelphia, 2009: 544-549.

KOSYACHENKO L A, MATHEW X, PAULSON P D, et al.. Optical and recombination losses in thin-film Cu(In, Ga)Se2 solar cells[J].Sol. Energy Mater. Sol. Cells, 2014, 130:291-302.

MACLEOD H A. Thin-film Optical Filters [M]. London:Adam Higer LTD, 1969.

ASTM G173-03. Standard Tables for Reference Solar Spectral Irradiances: Direct Normal and Hemispherical on 37° Tilted Surface[S]. West Conshohocken: ASTM International, 2003.

陈明, 魏永强, 杨柯.光伏玻璃表面减反和自洁SiO2/TiO2双层膜的制备和性能[J].玻璃, 2017, 44(4):10-14.

CHEN M, WEI Y Q, YANG K. Preparation and performance of SiO2/TiO2 anti-reflective and self-cleaning films on PV glass surface[J].Glass, 2017, 44(4):10-14. (in Chinese)

RUBIN M. Optical properties of soda lime silica glasses[J].Sol. Energy Mater., 1985, 12(4):275-288.

MCINTOSH K R, COTSELL J N, NORRIS A W, et al.. An optical comparison of silicone and EVA encapsulants under various spectra[C].Proceedings of 2010 35th IEEE Photovoltaic Specialists Conference, Honolulu, 2010: 269-274.

TREHARNE R E, SEYMOUR-PIERCE A, DUROSE K, et al.. Optical design and fabrication of fully sputtered CdTe/CdS solar cells[J].J. Phys.:Conf. Ser., 2011, 286:012038-1-8.

ALYAMANI A, SAYARI A, ALBADRI A, et al.. Structural, morphological and optical characterizations of ZnO:Al thin films grown on silicon substrates by pulsed laser deposition[J].Eur. Phys. J. Plus, 2016, 131(9):328-1-8.

DUMONT E, DUGNOILLE B, BIENFAIT S. Simultaneous determination of the optical properties and of the structure of r.f.-sputtered ZnO thin films[J].Thin Solid Films, 1999, 353(1-2):93-99.

PAULSON P D, BIRKMIRE R W, SHAFARMAN W N. Optical characterization of CuIn1-xGaxSe2 alloy thin films by spectroscopic ellipsometry[J].J. Appl. Phys., 2003, 94(2):879-888.

方容川.固体光谱学[M].合肥:中国科学技术大学出版社, 2001.

FANG R C. Solid State Spectroscopy [M]. Hefei:University of Science and Technology of China Press, 2001. (in Chinese)

PALIK E D. Handbook of Optical Constants of Solids Ⅱ[M]. Boston:Academic Press, 1991.

BORN M, WOLF E, BHATIAA B, et al.. Principles of Optics: Electromagnetic Theory of Propagation, Interference and Diffraction of Light [M]. 7th ed. Cambridge:Cambridge University Press, 1999.

杨杰, 吴凡.粗糙表面可见光散射特性的实验研究[J].中国测试, 2009, 35(2):125-128.

YANG J, WU F. Experimental research on visible light scattering characteristics of rough surfaces[J].China Meas.Test, 2009, 35(2):125-128. (in Chinese)

GREEN M A, EMERY K, HISHIKAWA Y, et al.. Solar cell efficiency tables(version 39)[J].Prog. Photovolt.:Res. Appl., 2012, 20(1):12-20.

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