Others also read
| At Step Change 2025, in connection with Glass Performance Days 2025, eLstar Dynamics wowed us with their smart glass tech that dynamically shifts from ultra-dark (0.1% transparency!) to crystal clear (up to 70%).
| In this ninth episode of #AskGlaston flat tempering series, we explore how to optimize energy efficiency in the case of short loadings.
| Viprotron has developed a new technology for the exit of the furnace, that allows the measurement of the distortion of tempered glass with high precision and unparalleled repeatability.
| ASTM has introduced a new standard, ASTM E3401, to guide the safe use of laminated glass in swimming pools, aquariums, and other applications subject to hydrostatic loads.
| In this eighth episode, we delve into optimizing energy efficiency in Low-E production.
| New international standards are reshaping the way modern façade glass is designed, balancing security performance with comfort, safety, and multifunctionality.
| Discover how TPS® boosts IGU longevity and energy performance in this Glastory blog and download the presentation.
| The growing use of glass in modern architecture has increased the importance of laminated safety glass (LSG), prompting new research into how production processes impact its long-term durability and safety.
| In the seventh episode of the #AskGlaston flat tempering series, the focus is on the Tempering Autopilot.
| Dive into the blog to learn how cutting-edge solutions are making ultra-thin glass production possible—and scalable.
| In this sixth episode of #AskGlaston flat tempering series, we explore how to avoid loading delays in tempering.
| Mikko Rantala on Glastory: Glass tempering is an energy-hungry process, and not just because of the heat.
| As labor shortages and efficiency demands grow, automation is transforming glass tempering—starting with AI-driven batch building that boosts productivity, cuts energy use, and maximizes furnace performance.
| This paper presents a groundbreaking technological development in the optical quality of tempered glass.
| This study examines prestressed glass specimens that are 0.5mm, 1.1mm, and 2.1mm thick in comparison to glass of the same thicknesses that have not been enhanced by the novel stiffening method.
| Modern tempering technologies offer impressive energy efficiencies for glass processors. But, have you ever come across energy-saving claims that seem too good to be true?
| 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.
| Optical stress measurement in tempered glass has its challenges. Stresses can be measured optically based on the optical anisotropy behavior of the glass.
| What glass processes gain the most from automation? In this blog, we’ll focus on some of the particularly promising application areas.
| The two common defects—White Haze and Anisotropy—are often misunderstood but are not the same.
| The latest Glastory blog gives insights on the experiences of the tempering process Autopilot users.
| Glass is most often heat treated before using it as a structural material. In this context, thermal tempering is the most effective and efficient method to enhance the load bearing capacity and strength of glass.
| Implementing quality controls and checkpoints during production and inspecting 100% of the tempering process, guarantees less rejections in the field converting into more profit.
| Glass tempering is a process that can be made in many ways to get tempered glass that meets the standards. The selected way is usually chosen by the operator and is almost always based on experience instead of science.
| Application to cantilevered balustrades