State-of-the-art laser structuring technology opens completely new possibilities for the production of semi-transparent and aesthetically pleasing PV modules. Thanks to the highest precision, there is no need to worry about disruptive interference. Even with complex contours, free-form processing enables extended design freedom.
The innovative technology also allows logos and even images to be easily created not only within a module, but also on much larger surfaces by cleverly combining individual modules with each other.
If you want to learn more, please visit our website.
The basic idea behind laser structuring is to selectively remove or structure thin functional layers on glass while ensuring the highest precision and quality. These functional layers can include transparent conductive oxides (TCO), metallic layers or photovoltaic absorber layers.
The right laser source is selected extremely carefully, taking into account pulse length, pulse energy and beam shaping to achieve the best possible results. Our expertise in laser source selection and matching is the key to outstanding processing efficiency and quality.
We rely on years of experience and a modern laboratory to analyze and continuously optimize the quality of material processing. With our support, you can achieve perfection in your PV modules and create innovative solutions that are both aesthetically pleasing and functional.
Laser structuring technology enables the development of PV modules that not only generate energy efficiently, but also take the design of your application to a new level. From architecture to solar technology, rely on precision and creativity with our laser structuring technology.
JobShop - Laser technology as a service
Through our JobShop we offer you the chance to benefit from 4JET's high-tech equipment for patterning glass without having to make the initial investment for your own laser processing systems. Our MicroFab location in Prutting near Rosenheim not only handles all production steps from initial sampling to 100% quality control, but also the procurement of substrates, cleaning and packaging as well as door-to-door logistics.
If you are interested in purchasing one of our precision laser systems for structuring glass, here is your opportunity to gain initial experience with the quality of laser patterning.
For more information about our laser processing service, please contact us at any time or visit our JobShop website.
Scrubbing worktops, unblocking your dishwasher or fatbergs building up in our sewers could be a thing of the past, thanks to new laser technology for structuring metallic surfaces, currently being developed by a European photonics consortium. Preventing water, dirt or grease from ever attaching, the treated metal will mean fridges or oven doors remain clean for a longer period, without using detergents or heat.
‘Textured’ by some of the most powerful lasers in the world, this new laser-treated metal will have microscopic ‘spikes’ or ‘ridges’ that act like a bed of nails and stop dirt or liquids attaching themselves. The laser creates an ‘amphiphobic’ – or repellent to water and oils – surface upon the metal similar to the defense mechanisms found in nature like Lotus leaves or springtails‘ skin, enabling water and oil to simply ‘roll off’. Similar micro-nano-structures reduce the build-up of bacteria meaning a surface never becomes dirty.
Although this work is currently being carried out on metal, the scientists say the laser-structuring technique works with other materials, like plastic and glass. While we normally rely on surface coatings like Teflon to make easy-to-clean products, they can suffer from drawbacks if the covering breaks apart that can then emit toxic particles or gases.
The direct laser treatment of the surface – what the team calls ‘surface functionalization’ or a way of altering the properties of the surface – therefore, provides an environmentally friendly and much safer alternative. Teaming up with home appliance giant Bosch, the LAMpAS consortium is tailoring sheet metal to several different applications.
Microtreat contains other products and information you need, so please check it out.
LAMpAS project coordinator Prof Dr Andrés Fabian Lasagni said: “We are targeting related use cases: medical surfaces in hospitals, like stainless steel antibacterial surfaces; packaging machines in the pharma industry that need to be disinfected; machines in the food processing sector that need be continually cleaned and where hygiene is paramount.”
While sheet metal has previously been textured to repel water and bacteria, preventing fingerprints remains a novel approach for laser-treated metal. Carved specifically to repel grease and fat, the metal will have ‘amphiphobic’ properties, or the ability to repel water and oil simultaneously.
The laser technology leader in the European Photonics Industry Consortium (EPIC) Dr Francesca Moglia said: “We are treating sheet metal to obtain what we at LAMpAS call ‘anti-fingerprint’ characteristics. If we use this metal on the outside of a refrigerator, an oven or kitchen surface, the user would not have to clean finger or hand marks so often – meaning your fridge always stays shiny.”
“The treatment of surfaces with special laser radiation and beam transport systems to improve their antibacterial properties opens up new frontiers in applications. LAMpAS is using high-power ultrashort-pulsed lasers to create a rough micro-topography on sheet metal that will cause liquids to ‘glide’ across the surface, thus, reducing the formation of a biofilm,” she continued.
Called ‘LAMpAS’, short for the ‘high throughput laser structuring with multiscale periodic feature sizes for advanced surface functionalities’, the team is working on producing self-cleaning metal sheets on an industrial scale.The metal surfaces are textured using industrial photonics devices: high-power, ultrashort-pulsed lasers are used in combination with high-performance scanning heads by utilizing an innovative beam delivery method enabling movements of up to 100 m/s. “The idea of using photonics or high-powered lasers to create tiny structures on metal is nothing new but has always been too expensive to produce and too time-consuming.”
“Our laser system will allow us to treat more than one square meter of sheet metal per minute covering a potentially growing market that could reach nine-digit revenues per year in the home-appliance sector alone. With our innovative Direct Laser Interference Pattering (DLIP) – Polygon Scanner head we will be able to treat metal with a 1.5 kW novel ps-laser source, with scanning speeds over 100 m/s,” said Prof Lasagni.
At present, the LAMpAS team are focusing their expertise on flat metallic surfaces, but beyond the project see a broad market for large areas of other materials. “Anything that requires complete hygiene will benefit greatly from antibacterial surfaces such as hospital and operation environments that must be continually cleaned during surgical procedures.”
Coordinated in Germany by the Technical University Dresden, the LAMpAS consortium has received a grant of € 5.1 M from the European Union’s Horizon research and innovation programme under Grant Agreement No. . It is an initiative of the Photonics Public Private Partnership. (Source: photonics21)
If you want to learn more, please visit our website laser patterning system.