固态全无机电致变色玻璃窗透过率与遮蔽系数测试与分析*

doi:10.13385/j.cnki.vacuum.2023.01.02

真空 ›› 2023, Vol. 60 ›› Issue (1): 13-16.doi: 10.13385/j.cnki.vacuum.2023.01.02

固态全无机电致变色玻璃窗透过率与遮蔽系数测试与分析^*

酆纲^1,2, 孟政^1,2,3, 杨学东⁴, 张浩运⁴, 余刚^1,3, 高辉¹, 王伟才¹, 宋猛¹, 孙勇^1,3, 孔壮^1,3, 贾金升¹, 汪洪^1,3

1.中国建筑材料科学研究总院有限公司绿色建筑材料国家重点实验室,北京 100024;
2.中建材科创新技术研究院（山东）有限公司山东省无机功能材料与智能制造重点实验室,山东枣庄 277100;
3.太阳能与建筑节能玻璃材料加工技术北京市重点实验室,北京 100024;
4.中国国检测试控股集团股份有限公司,北京100024

收稿日期:2021-12-29 出版日期:2023-01-25 发布日期:2023-02-07
通讯作者: 孟政,博士,高级工程师。
作者简介:酆纲（1972-）,男,北京市人,工程师。
基金资助:
*国家重点研发计划课题：固态全无机电致/热致变色镀膜玻璃制造技术与产业化示范（NOs.2016YFB0303901）

Measurement and Analysis of Light Transmittance and Shielding Coefficient of All Inorganic Solid-state Electrochromic Window

FENG Gang^1,2, MENG Zheng^1,2,3, YANG Xue-dong⁴, ZHANG Hao-yun⁴, YU Gang^1,3, GAO Hui¹, WANG Wei-cai¹, SONG Meng¹, SUN Yong^1,3, KONG Zhuang^1,3, JIA Jin-sheng¹, WANG Hong^1,3

1. State Key Laboratory of Green Building Materials, China Building Materials Academy, Beijing 100024, China;
2. Shandong Key Laboratory of Inorganic Functional Materials and Intelligent Manufacturing, CNBM Technology Innovation Academy, Zaozhuang 277100, China;
3. Beijing Key Laboratory of Solar Energy and Building Energy-saving Glass Materials Processing Technology, Beijing 100024, China;
4. China Building Material Test & Certification Group, Beijing 100024, China

Received:2021-12-29 Online:2023-01-25 Published:2023-02-07

摘要/Abstract

摘要： 为了更好地发挥电致变色玻璃主动调控光谱的属性,为电致变色玻璃在建筑上的应用提供理论指导,以两玻一腔中空玻璃为例讨论了可见光透过率和遮蔽系数（节能效果）变化。研究发现,获得更大的可见光透过率差（褪色态-着色态）重点是要提高电致变色玻璃透过率,但相比于成本更高的电致变色玻璃,提高Low-E玻璃透过率更为现实。为了更大限度地发挥电致变色玻璃的节能特性,分别将电致变色玻璃放置于中空玻璃的室内侧与室外侧测试,结果表明当电致变色玻璃位于室外侧时,遮蔽系数变化幅度最大（0.46）,更能适应多种场景下的使用,但同时也对电致变色玻璃的膜层性能提出了更高的要求。

关键词: 电致变色玻璃, 褪色态, 着色态, 可见光透过率, 遮蔽系数, 中空玻璃, Low-E玻璃

Abstract: In order to make better use of the properties of active spectrum control of electrochromic glass and provide theoretical support for the application of electrochromic glass in architecture, the sealed insulating glass unit was taken as an example to discuss the changes of visible light transmittance and shielding coefficient(energy saving effect). It is found that in order to obtain a larger visible light transmittance difference(bleach state minus color state), the key point is to improve the transmittance of electrochromic glass. However, compared with the electrochromic glass with higher cost, it is more realistic to improve the transmittance of Low-E glass.In order to give full play to the energy-saving characteristics of electrochromic glass, the electrochromic glass was placed on the outdoor side and indoor side of insulating glass respectively for testing. The results show that when the electrochromic glass is located on the outdoor side, the change of shielding coefficient is the largest(0.46), which is more suitable for a variety of scenarios. At the same time, the better performance of electrochromic glass film is required.

Key words: electrochromic glass, bleach state, color state, visible light transmittance, shielding coefficient, insulating glass, Low-E glass

中图分类号:

TQ171

酆纲, 孟政, 杨学东, 张浩运, 余刚, 高辉, 王伟才, 宋猛, 孙勇, 孔壮, 贾金升, 汪洪. 固态全无机电致变色玻璃窗透过率与遮蔽系数测试与分析^*[J]. 真空, 2023, 60(1): 13-16.

FENG Gang, MENG Zheng, YANG Xue-dong, ZHANG Hao-yun, YU Gang, GAO Hui, WANG Wei-cai, SONG Meng, SUN Yong, KONG Zhuang, JIA Jin-sheng, WANG Hong. Measurement and Analysis of Light Transmittance and Shielding Coefficient of All Inorganic Solid-state Electrochromic Window[J]. VACUUM, 2023, 60(1): 13-16.

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固态全无机电致变色玻璃窗透过率与遮蔽系数测试与分析^*

Measurement and Analysis of Light Transmittance and Shielding Coefficient of All Inorganic Solid-state Electrochromic Window

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