Research and Development

The active thermography, ie a thermal imaging of components into which a defined heat flow was generated, is a non-destructive component test, with which defects in the component (cracks, inclusions), but also defective joints can be detected with simple means. Previous excitation techniques, such as halogen or flash discharge lamps, heat the component from the outside, causing the heat to flow in, be reflected at the first boundary layer, and come back to the surface where it can be detected. It would be better to generate the heat inside the component and to look at the heat flow to the surface. This is possible with ultrasonic excitation, but in which the component must be touched for exciting, and the non-contact induction excitation. The task of the IFF GmbH was the optimization of the existing generator technology and the development of special inductors for excitation in reflection arrangement (keyword: “transparent inductors”), in which the exciting inductors and the thermal imaging camera are located on the same side of the component. Together with our partner company edevis GmbH in Stuttgart, starting with this project induction thermography systems are developed and built, which are used very successfully by manufacturing industry partners.

The overall theme of this project was the development of noise-optimized gears that would be used in the automotive industry (gearbox) or in a tool manufacturer (circular saw) to reduce the noise emission. The noise reduction of the newly developed hybrid gears is achieved by a circumferential layer of plastic (adhesive layer) in the gear ridge, which provide the sound attenuation during operation but should have the properties of a metal gear. IFF GmbH had the task of reducing the process time for curing the adhesive layer to a level that was tolerable for the planned production times. Instead of a time-intensive oven curing, the adhesive crosslinking takes place by means of significantly more efficient induction heating.

The overall topic of this project was the development of a process methodology for the rapid hardening of CfK components using induction technology. Previous methods of producing carbon fiber reinforced components by means of resin infusion and resin injection techniques require large metallic shapes that are unsuitable for optimal curing conditions. The task of IFF GmbH was to find and qualify more usable (even heatable) mold materials (eg Hextool) and to develop alternative heating mechanisms based on induction technology in order to minimize the energy and time consumption in the production of these fiber composite components.

The purpose of the braided pultrusion project was to simplify and accelerate the production of long CFRP profiles with a thermoplastic matrix (eg pipes) by targeted heat input into the fibers. The heat to be introduced serves to consolidate the textile preforms produced by means of braiding pultrusion and impregnated with resin. It is not inductively introduced into the fibers, but touching by conduction (electrical resistance heating) with frequency-optimized alternating current. The main task of the IFF GmbH was the development and qualification of a safe operable contacting method of the moving preforms and an associated generator, which was successfully implemented.

This project was concerned with the development of a methodology for the structural quick gluing of fasteners. These fasteners should be preconditioned with a dry adhesive so that the user does not have to apply the adhesive himself (incorrect metering, contamination), but can only perform the bonding process via an inductive heating process. The whole thing should be carried out manually and lead to a strong bond in a few seconds, without drilling the joining partner would be necessary. IFF GmbH has developed a special inductor for such fasteners and a mobile induction generator.