Technological watch

Electroimpact Uses Victrex’s PAEK-based UDT to Produce Aerospace Components

Electroimpact, a provider of factory automation and tooling solutions, was able to increase laydown speeds of thermoplastic unidirectional tape (TP UDT) to 4000 inches per minute (IPM), using their enhanced Automated Fiber Placement (AFP) processing technology. The high-speed rates were possible by working together with Victrex and by relying on the unique properties of the company´s VICTREX AE 250 LMPAEK UDT.
Overcoming Issues in Making of Composite Structures
Currently, large composite structures in aerospace such as wings, and fuselage are virtually all thermoset based. However, the challenge with the thermoset composites is that they require a lengthy cure in an autoclave large enough for the structure. The autoclave is a production bottleneck and requires a considerable amount of energy to operate.
With sustainability being an important driver for the aerospace industry, OEM’s and tiers are not only looking to improve fuel efficiency of aircraft but also at improving efficiencies throughout the supply chain. The substantial benefit thermoplastic composites offer has, for some considerable time, been investigated and this has led to an increasing adoption for the manufacture of smaller parts. Moreover, thermoplastic composites can be processed Out of Autoclave (OoA) so manufacturing processes have been developed to take advantage of their potential for high-speed production. Recyclability of thermoplastic composites is another major advantage as well.
New Laser Technology to Enhance AFP Processing Technology
The significance of processing thermoplastic UDT at 4000 IPM layup speeds with the Variable Spot Size (VSS) Laser is, for the first time that we know of, that thermoplastics are able to achieve thermoset lay-up speeds. These developments can help eliminate the need for autoclave cure, offer major, and new, throughput advantages for thermoplastics.” explains Michael Assadi, chief engineer at Electroimpact.
Electroimpact has enhanced existing AFP processing technology through the deployment of a new laser heating system with the potential to revolutionize thermal processing for the aerospace industry. Assadi adds, “We are really excited at Electroimpact to offer this new laser technology and using the high-performing LMPAEK composite material from Victrex on a broader scale to meet unmet customer needs. I’m convinced, that based on ongoing in-depth support from Victrex at every stage of the project, high speed production and high performance of the advanced VICTREX AE 250 UDT will enable the production of large-scale aerospace structural components in the years to come.”
Test Program to Test Victrex LMPAEK UDT
VICTREX AE 250 UDT is a novel, high-performance thermoplastic composite prepreg tape that was designed by Victrex to have mechanical, physical and chemical resistance properties typical of the Polyaryletherketone (PAEK) polymer family, such as PEEK, but with a 40 °C lower crystalline melting temperature, at only 305°C.
Electroimpact has already gone one step further and trialled in-situ production with VICTREX AE 250 UDT. A test program comparing several different materials demonstrated, that the Victrex LMPAEK UDT delivered the best performance producing porosity-free laminations, including the most dimensionally uniform and even distribution of fiber in the resin.
As a result, a high-quality component can be produced without any additional processing steps after layup, eliminating the need for oven consolidation. In-situ manufacturing has long been considered the holy grail for aerospace composite structures.
Key to the cooperation is the joint offering of optimized AFP process that delivers impressive time and energy-saving benefits in both in-situ and ‘Out of Autoclave’ (OoA) consolidation as compared to another polyketone UD tape intended for similar applications.

Publication date: 14/01/2021

Omnexus (news)


This project has received funding from the European Union’s Horizon 2020 research and innovation programme for the Clean Sky Joint Technology Initiative under grant agreement No 887073.