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A platform for research: civil engineering, architecture and urbanism
Optical anisotropy effects in laminated tempered glass
https://orcid.org/http://orcid.org/0000-0003-2052-2378
Minor fluctuations in the tempering process of architectural glass lead to residual stress differences resulting in birefringence and undesired optical iridescence, also known as anisotropy effects. The control of anisotropies, which are quantified as optical retardation, is limited to monolithic glass. In modern architecture, laminated glass panes consisting of an interlayer of polyvinyl butyral or ionomer (SentryGlas®) are frequently applied. In this paper, photoelastic studies are performed on laminated glass panes before and after the lamination process to evaluate their effect and to investigate the influence of the superposition of different orientated glass panes. An influence from the interlayer is not markedly evident. Aside from a few outliers, there are percentage deviations of less than 6% in the 95% quantile value. The influence of the retardation pattern of the individual sheets is significant; depending on their position in the furnace, the superposition of the individual glass sheets results in a dot-shaped or a strip-shaped pattern. The experiments have demonstrated that retardation can be cumulative or reduced depending on the azimuth angle of the individual retardation value. Finally, six glass panes were installed in an outdoor test rig to observe the optical appearance under various light condition and different viewing points. Here, a correlation of the findings from the previous retardation measurements is clearly revealed.
Optical anisotropy effects in laminated tempered glass
https://orcid.org/http://orcid.org/0000-0003-2052-2378
Minor fluctuations in the tempering process of architectural glass lead to residual stress differences resulting in birefringence and undesired optical iridescence, also known as anisotropy effects. The control of anisotropies, which are quantified as optical retardation, is limited to monolithic glass. In modern architecture, laminated glass panes consisting of an interlayer of polyvinyl butyral or ionomer (SentryGlas®) are frequently applied. In this paper, photoelastic studies are performed on laminated glass panes before and after the lamination process to evaluate their effect and to investigate the influence of the superposition of different orientated glass panes. An influence from the interlayer is not markedly evident. Aside from a few outliers, there are percentage deviations of less than 6% in the 95% quantile value. The influence of the retardation pattern of the individual sheets is significant; depending on their position in the furnace, the superposition of the individual glass sheets results in a dot-shaped or a strip-shaped pattern. The experiments have demonstrated that retardation can be cumulative or reduced depending on the azimuth angle of the individual retardation value. Finally, six glass panes were installed in an outdoor test rig to observe the optical appearance under various light condition and different viewing points. Here, a correlation of the findings from the previous retardation measurements is clearly revealed.
Optical anisotropy effects in laminated tempered glass
https://orcid.org/http://orcid.org/0000-0003-2052-2378
Minor fluctuations in the tempering process of architectural glass lead to residual stress differences resulting in birefringence and undesired optical iridescence, also known as anisotropy effects. The control of anisotropies, which are quantified as optical retardation, is limited to monolithic glass. In modern architecture, laminated glass panes consisting of an interlayer of polyvinyl butyral or ionomer (SentryGlas®) are frequently applied. In this paper, photoelastic studies are performed on laminated glass panes before and after the lamination process to evaluate their effect and to investigate the influence of the superposition of different orientated glass panes. An influence from the interlayer is not markedly evident. Aside from a few outliers, there are percentage deviations of less than 6% in the 95% quantile value. The influence of the retardation pattern of the individual sheets is significant; depending on their position in the furnace, the superposition of the individual glass sheets results in a dot-shaped or a strip-shaped pattern. The experiments have demonstrated that retardation can be cumulative or reduced depending on the azimuth angle of the individual retardation value. Finally, six glass panes were installed in an outdoor test rig to observe the optical appearance under various light condition and different viewing points. Here, a correlation of the findings from the previous retardation measurements is clearly revealed.
Optical anisotropy effects in laminated tempered glass
Glass Struct Eng
Efferz, Lena (author) / Dix, Steffen (author) / Schuler, Christian (author) / Kolling, Stefan (author)
2025-03-01
Article (Journal)
Electronic Resource
English
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