Technologies

DETERMINATION OF REACTION ENTHALPIES OF MOISTURE-SENSITIVE MATERIALS UNDER INERT GAS ATMOSPHERE | The enthalpy measurement of mixing reactions during the synthesis of air-sensitive materials must be carried out under inert conditions and thus places special demands on the measurement setup. One example of moisture-sensitive materials are sulfide solid-state electrolytes, which may be used in future solid-state batteries (ASSBs). To make these materials economically attractive, Fraunhofer IFAM is researching the scale-up of the synthesis process. For the upscaling of the syntheses, reaction enthalpies are required, which must be measured in an inert gas atmosphere.

Non-stick coatings have been among the most popular coatings for cookware such as pans, casseroles or cutlery for decades due to their ease of use and cleaning. Common nonstick coatings are made with a PTFE or sol-gel base. However, PTFE-type coatings face a ban in the near future due to possible PFAS restrictions by the EU. In addition, these coatings have only limited durability and lose their non-stick effect over time. In addition, they are not very stable mechanically and have to be baked in an oven, which involves high energy consumption. New, sustainable solutions with good non-stick properties are therefore needed. Researchers at Fraunhofer IFAM have developed PLASLON® coating, a PFAS-free alternative, which is characterized by its excellent non-stick properties in combination with its high durability.

The new cryogenic testing machine of Fraunhofer IFAM enables to determine the material and small component properties of polymers, composites, and adhesive joints at cryogenic temperatures.

MANUFACTURING OF FRP COMPONENTS USING A FUNCTIONALIZED RELEASE FILM | Due to their low weight and strength, components made of fiber-reinforced plastics (FRP) are in particularly high demand in a wide range of industries, such as the aerospace or automotive industries. However, conventional demolding of FRP components by using release agents is very cost and labor intensive. In addition, the release agents can have harmful effects on the environment. At Fraunhofer IFAM, a plasma-coated release film has been developed which allows thermoset plastic components to be manufactured and safely demolded without the use of release agents. The component surface is free of contamination and can be painted or bonded directly.

ADHESIVE FILMS AND COATINGS BASED ON BENZOXAZINE - STORAGE-STABLE AND NON-MELTABLE | Repairing fiber composite components is often time-consuming and requires multiple processing steps and curing cycles of the resin. Typical restoration of the function or appearance of a damaged area is carried out using a wet lamination process or application of reinforcing structures on the surface. Therefore, if an adhesive film or coating based on benzoxazines is used instead this enables comparatively simpler repair and adhesive bonding, with final strength being achieved within 30 minutes.

PLASMA COATINGS: CHEMICAL-FREE THIN FILMS FOR NEW SURFACE AND PRODUCT PROPERTIES | The demand for special functional coatings for products and semi-finished products is very high in many industrial sectors - from automotive production and plastics processing to medical technology or biotechnology. Fraunhofer IFAM is researching and developing plasma-assisted coating processes which decisively improve the range of properties of these (semi-finished) products almost independently of the material used. And without the use of chemicals! This makes these processes particularly interesting at present, because it helps companies to comply with regulations such as the REACH regulation or the HSE guidelines.

SMART WALLPAPER FOR EASY BATTERY AND RADIO-FREE INTEGRATION OF IoT DEVICES | Smart homes aim to install technical systems wherever they are needed in the house. However, the necessary power and communication connections are not always available. In the "ConText" project, Fraunhofer IFAM is developing a smart wallpaper that can be easily installed in living areas without great effort.

INLINE-BLASTING PROCESSES FOR CLEANING, ACTIVATION AND REPAIR OF SURFACES | Classical compressed air blasting requires the use of blasting booths or complex temporary protective measures to clean surfaces or remove coatings. Much simpler is to use compact and mobile vacuum suction blasting prior to, for example, adhesive bonding, painting/lacquering, coating, or repair work. In this method an industrial vacuum system generates a reduced pressure in a closed head through which the abrasive is accelerated onto the surface and after the blasting process is immediately extracted again. This means that dust-free blasting processes can even be performed in-line under sensitive production conditions.

RESIDUE-FREE AND DRY CLEANING OF COMPONENTS | Contaminants and release agents can be removed from components using CO2 snow blasting processes. This in-line technique involves the sudden expansion of liquid CO2, whereby solid crystals of CO2 snow form in a nozzle on introducing compressed air. These are blasted at the surface to be cleaned. There is no damage due to the immediate sublimation, and even sensitive surfaces can be effectively cleaned. Compared to conventional blasting grit, the CO2 snow evaporates and can be extracted without leaving residues. The process is eco-friendly because CO2 can be recovered as a byproduct from many chemical processes.

Metal nanoparticles are becoming increasingly important in many industrial sectors. Being applied as additives or functional coatings, they can equip various products with new properties, such as catalytic or antibacterial effectiveness. However, the technical complexity and the time and resource costs of the current manufacturing processes have significantly limited potential applications of the metal nanoparticles up to now. The Fraunhofer IFAM has developed an innovative solution for this by using a novel atmospheric pressure (AP) plasma technique.