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| What glass processes gain the most from automation? In this blog, we’ll focus on some of the particularly promising application areas.
| When finding, training and retaining personnel for routine jobs is a challenge, processing automation offers a game-changing solution.
| Robots are finding their way into the flat glass industry, improving not only process reliability but also product quality. But where exactly are they being used and what specific advantages do they offer?
| 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.
| What are the real benefits that robotics, the IOT (Internet of Things) and the Automatic machines can bring to glass grinding?
| Digitalization of machines requires standardized language for machine communication – and OPC UA is the perfect choice.
| In the latest Glastory blog post, Antti Aronen analyzes the transformative potential of automated glass tempering.
| This paper presents an approach to the estimation of a window shape for increasing the adaptability of glass façade-cleaning robots to different buildings.
| In this episode, Gennadi Schadrin, Director Research & Development IG, shares insights into its creation and the remarkable benefits it brings to glass processors.
| This is the first video in Glaston's new #AskGlaston Insulating Glass Manufacturing Series.
| This research investigates robotically fabricated polychromatic float glass for architectural applications.
| Color Depth is a material-based research project investigating the optical and structural properties of thick glass.
| This paper shows different Pummel classifications that can currently be found on the market. Subsequently, approaches to the automatization and standardization of the execution and especially the evaluation of the Pummel test are shown.
| In the second episode of #AskGlaston Flat Tempering Series, we will talk about the new solution to estimate the stress level in glass – online.
| This first episode is devoted to the white haze phenomenon – one of the most asked about issues in the history of #AskGlaston.
| After seaming, grinding glass edges is another important work step in glass edge processing. The process is primarily used to remove overbreaks and underbreaks at the edges and to process the glass sheets to size.
| In glass edge processing, cutting the glass sheet is directly followed by the seaming process. Fully unprocessed glass edges exhibit overbreaks and underbreaks, conchoidal fractures, as well as micro-cracks along the broken edge.
| In glass edge processing, the requirements for the finished components can vary greatly depending on the location and purpose.
| Today, almost all new devices – from home appliances to production equipment – are connected. Rapid development in consumer electronics has been increasingly moving towards industrial use. In the glass industry, this development is still in its early stages.
| When people talk about the future of production, they can't do so without using the term "smart factory." But what is it? How does a smart factory work? And what does it have to do with OPC UA?
| Few materials in human history have been made for as long or used in as many ways as glass. Ancient peoples molded it and poured it; later cultures discovered how to spin and blow glass into unique, dazzling shapes.
| Glaston is working hard to make tempering furnaces more automated.
| The new LiSEC glass edge deletion machines are equipped with improved sensor technology. This measures with greater precision and therefore guarantees constantly high finishing quality of the glass edges.
| Digitalisation is not only something for start-ups or major enterprises. It applies just as naturally to many skilled trade businesses.