Landing on short, unpaved grass and gravel runways was previously reserved for turboprop aircraft, but as of recently, this type of terrain is no longer off limits to the new PC-24. It can take off after just 890m and requires only 720m for landing. This is in part due to its base weight of only 5.3 tons brought about by the numerous carbon and glass-fibre components which make up the PC-24. For its cutting operations, Pilatus has for years relied on technology from the Rhein Valley in Switzerland. In 2018 Pilatus decided once again to opt for a highly automated Zünd digital cutting system.
“Commitment to production location and the ‘Swissness’ that goes along with it are one thing; but at least as important are state-of-the-art production cells equipped with cutting-edge technology.”
Key to this are permanent reduction of costs, productivity optimisation, and the ability to implement modern production technologies.
Things were different back in 1959. That's when the PC-6 Porter took off for the very first time at Stans Airfield near Lucerne, Switzerland. It was a sturdy, all-metal universal aircraft that many would refer to as a "Jeep with wings" – a plane with the versatility of a Swiss Army Knife. The PC-6 were still assembled by hand, which necessitated an experienced workforce and tolerances that were much greater than they are today. The company's latest aircraft type, the PC-24, consists of innumerable parts, many of them milled at tolerances in the micron range. Assembly is much faster now, made possible only because of the latest advances in production technologies.
As of this year, the PC-6 is no longer being built, a success story that came to an end after a production run of 500 planes. Its successor, the PC-12, which has been sold globally more than 1,650 times since 1994, is the most popular single-engine turboprop aircraft on the market.
Pilatus began using carbon fibre parts early on in its history of manufacturing airplanes. Already for the PC-6, first GFRP and CFRP components were laid up by hand, albeit still in limited quantities.
In the aircraft industry, almost everything revolves around weight reduction. As a result, more and more parts are made from carbon and glass fibre. Major advantages of these materials are their high rigidity and toughness, as well as their wear resistance. The challenge, however, lies in balancing weight, stability, and cost.
"In addition, there are factors such as payload and usable space that have to be maximised as much as possible."
At Pilatus no load-bearing parts are made of CFRP, but the company's R&D is busy working on that. The PC-24 uses composites mainly for interior and exterior cladding. The engine casings and wingtips, too, are made of carbon fibre, as well as landing gear doors, air ducts, various pipes, covers, and trailing edges on wings.
Prepreg is delivered in rolls by refrigerated trucks and stored in freezers at -19°C. To bring the material to room temperature for processing, it is taken out of the cooler the night before. It can remain at room temperature for 5 to 20 days before the resin begins to react and cure. Pilatus processes around five rolls of approx. 90m2 daily, or about 90,000m2 per year. And the rate of consumption is steadily increasing; today more than half of all CFRP and GFRP components produced in the company's plastics department are installed in the new PC-24. For cutting prepreg, Pilatus has relied on Zünd digital cutting for more than 15 years. The PN-series cutter purchased at the time continues to reliably perform its duties; however, increased demand for carbon fibre components began to exceed capacity, which led to the addition of a Zünd G3 L-2500 in 2019. The G3 system single-ply cuts materials for the respective components in a largely automated process and labels cut pieces with an integrated inkjet module.
Once cutting is completed, the parts are kitted and put in cold storage until further processing. Depending on rigidity and strength requirements, a component can consist of up to 350 layers.
If no DXF file is available for parts or their individual layers, a digitiser comes into play that allows for easy capture and digitisation of part templates placed on the digitising table. Even minor changes to components previously released by the engineering department can be easily carried out and digitised using this system.
“When dealing with cost-intensive materials such as carbon or glass fibre, material efficiency and optimisation are always a concern,” explains Patrick Rohrer. “We are constantly working to increase utilisation and thereby reduce waste — particularly since we still have few options for recycling.”
In the meantime, waste rates have been reduced from 30% to 20%. The highly efficient nesting features in Zünd Cut Center - ZCC software play an important role in this. On one hand, cut parts are statically nested, which means parts, or rather their individual layers, are nested to create a set layout used repeatedly to complete the entire job.
“Dynamic nesting, meaning parts and layers from multiple jobs are nested and combined in a single cut file, is also used whenever it makes sense.” This further increases the degree of utilisation of the raw material.
“The fact that we can look back on 15 years of experience with Zünd cutting technology is important,” Rohrer concludes. “Zünd offers open and modular solutions with optional service contracts and extremely reliable software without short-lived updates. Exactly what we understand by real customer benefit.”
And Zünd attaches great importance to providing exemplary customer service – yet another trait the two companies have in common.