CIGS光伏组件用玻璃抽样检验方案探讨

材料导报

2021, Vol. 35

Issue (Z1): 195-197

无机非金属及其复合材料

CIGS光伏组件用玻璃抽样检验方案探讨

喻善均^1,2

1 重庆神华薄膜太阳能科技有限公司,重庆 400714
2 中国节能减排有限公司,北京 100011

Discussion on the Sampling Inspection Plan of CIGS Photovoltaic Module Glass

YU Shanjun^1,2

1 Chongqing Shenhua Film Solar Energy Technology Co., Ltd, Chongqing 400714, China
2 China Energy Conversation and Emission Reduction Co., Ltd, Beijing 100011, China

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摘要为提高来料检验水平,在综合考虑了检验成本、企业的解释程度的基础上,从规范玻璃检验的抽样方出发,通过采用IEC标准、国家标准、行业标准相结合的方式,探讨了CIGS光伏组件用衬底玻璃、盖板玻璃的抽样检验方案,通过对来料的分批,制定外观、尺寸、翘曲、透过率及包装等的抽样方案,以及检验的可接收质量限(AQL),并按相关规定对玻璃进行质量特性的合格与不合格判定。规范了CIGS光伏组件用玻璃抽样检验流程,对抽样检验进行标准化,进而确保玻璃原材料来料质量的稳定。

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关键词: 玻璃抽样检验接收质量限质量特性

Abstract: In order to improve the inspection level of incoming materials, on the basis of comprehensive consideration of inspection cost and the interpretation level of the enterprise, starting from the sampling party of the standard glass inspection, through the use of the combination of IEC standards, national standards and industry standards.Discussed the sampling inspection plan of substrate glass and cover glass for CIGS photovoltaic modules. By dividing the incoming materials into batches, formulating sampling plans for appearance, size, warpage, transmittance, and packaging, as well as the acceptable quality limit AQL of the inspection, the quality characteristics are qualified and unqualified in accordance with relevant regulations. Standardize the glass sampling inspection process for CIGS photovoltaic modules and standardize the sampling inspection to ensure the stability of the quality of glass raw materials.

Key words: glass sampling inspection AQL quality characteristics

发布日期: 2021-07-16

ZTFLH:

TB321

通讯作者: 20032432@chnenergy.com.cn

作者简介: 喻善均,重庆神华薄膜太阳能科技有限公司资深工程师。2009年3月毕业于河北理工大学材料学专业,获硕士学位。主要从事CIGS光伏组件品质管控工作,包括来料检验(IQC)、制程检验(PQC)。以第一作者在国内学术期刊上发表论文4篇,申请国家发明专利10项,已授权的实用新型专利5项。

引用本文:

喻善均. CIGS光伏组件用玻璃抽样检验方案探讨[J]. 材料导报, 2021, 35(Z1): 195-197.
YU Shanjun. Discussion on the Sampling Inspection Plan of CIGS Photovoltaic Module Glass. Materials Reports, 2021, 35(Z1): 195-197.

链接本文:

http://www.mater-rep.com/CN/ 或 http://www.mater-rep.com/CN/Y2021/V35/IZ1/195

1 李丽.工业技术,2015,2(23),165.
2 吕桂英.耐火材料,2013,47(2),158
3 GB/T 2828.1—2012/ISO 2859-1,1999. 中国标准出版社, 2012.
4 GB 11614—2009. 中国标准出版社, 2009.
5 JC/T 2170—2013. 中国建材工业出版社, 2013.

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