Le poids est l'ennemi.
Bugatti est fier de son savoir-faire. Les Chiron Pur Sport et Chiron Super Sport 300+ utilisent des matériaux et des techniques de pointe. En plus d'être motorisées par un moteur W16 couplé à quatre turbos, unique au monde, elles disposent d'embouts d'échappement en titane et imprimés en 3D. Bugatti affirme que cette pièce métallique est la première à être imprimée en 3D et homologuée pour la route. Ces embouts ne pèsent que 1,85 kg, soit 1,2 kg de moins que celle de la Chiron standard. Bugatti a utilisé quatre lasers de 400 watts pour imprimer les pièces en titane. Le procédé empile 4200 couches de poudre métallique qui sont ensuite fusionnées. Ces embouts résistent à la chaleur allant jusqu'à 650 degrés Celsius.
Bugatti utilise cette technique de fabrication depuis 2018. Le constructeur utilise aussi l'Inconel 718 qui est souvent utilisé dans les turbines à gaz, les vaisseaux spatiaux et les moteurs de fusée. Ce n'est pas non plus un processus de fabrication rapide, car il faut plusieurs jours pour imprimer un embout d'échappement. Une fois produit, Bugatti vérifie sa qualité avant de le sabler au corindon et d'y ajouter une peinture céramique noire.
Galerie: Bugatti - Impression 3D embout d'échappement
Bugatti adopte de nouvelles technologies qui non seulement rendent le processus de production plus efficace mais aussi rendent le développement d'une voiture plus facile que jamais. En 2016, la marque a commencé à utiliser la réalité virtuelle pour remplacer les véhicules de développement en argile. Cela permet non seulement d'accélérer le processus de développement si les concepteurs doivent changer quelque chose, mais aussi d'économiser de l'argent. Attendez-vous à ce que la technologie continue à transformer la conception et la production automobile, tout comme la technologie continue à modifier l'expérience de conduite.
Technological innovations - Bugatti prints trim covers made of titanium
As fine and accurate as a spider's web, yet as stable as a solid steel structure and extremely light: components created by means of 3D printing offer a range of benefits, but they are very complex to produce. This is why they are mostly used in the aerospace industry.
However, this production technology is also highly beneficial to the French luxury manufacturer Bugatti. The hyper sports cars Chiron Pur Sport1 and Chiron Super Sport 300+* are extreme in all aspects. That’s why they make use of vehicle parts that are produced using a 3D printer.
“Bugatti is all about French-style luxury and exceptional vehicles, but it’s a brand that stands for innovative technology, too,” says Stephan Winkelmann, President of Bugatti. “In addition to the iconic 8.0 litre 16-cylinder engine with 1,500 PS, technical innovation is just as much part of our brand essence – such as our components made of titanium or a special alloy that are produced by 3D printing.” Bugatti is in fact continuing a long-standing tradition here: the company founder Ettore Bugatti himself developed unique vehicles using groundbreaking technologies. His inventions include lightweight aluminium wheels and a hollow front axle.
As the only company in the automotive industry, Bugatti uses 3D printing to produce tailpipe trim covers made of titanium for its newly developed hyper sports car. The cover is the first visible part to be 3D-printed in metal that is officially approved for use on the roads. The approximately 22-centimetre long, 48-centimetre wide and 13-centimetre high trim cover at the rear of the Chiron Pur Sport weighs just 1,85 kilograms including grille and bracket – some 1.2 kilograms less than the cover on the Chiron.
Four 400-watt lasers simultaneously print titanium to produce the component – the wall thickness at the thinnest point is just 0.4 millimetres. Approximately 4,200 layers of metal powder are stacked on each other and are firmly fused together. “Wherever possible we designed the trim cover for the Chiron Pur Sport with a single layer so as to further reduce weight,” says Nils Weimann, Head of Body Development at Bugatti. “The minimal material thickness in multi-layer areas is made possible by its so-called lattice structure – where the cavity is filled with numerous filigree struts. In this way, the walls provide stable support for each other during the construction process – enabling minimal use of material. We use a bionic honeycomb structure in the single-layer area to increase the surface rigidity of the walls. Even large components gain a high degree of surface stiffness,” explains Weimann. Yet the filigree cover is still able to withstand temperatures of over 650 degrees Celsius. This is because the outer wall is double-layered for thermal insulation. In this way, the cover protects surrounding components from excessive heat dissipation under full engine load. At the same time, fresh air around the cover cools the component.
Bugatti has been using 3D printing since 2018
This is not the first time that Bugatti has developed components using 3D printing. The engineers have been producing this special trim cover for the Chiron Sport2 and Divo3 since 2018. The 2019 editions “La Voiture Noire4”, the ultimate Grand Tourisme for Bugatti enthusiasts, and the Centodieci5, a reinterpretation of the EB110, also make use of this printed component. The material Inconel® 718 – a particularly heat-resistant, hard and light nickel-chrome alloy – is used to produce a 53-centimetre wide and 22-centimetre long trim cover for the Chiron Sport. This material is otherwise used in gas turbines, aircraft turbine blades, space ships and transport rocket engines. Aluminium would melt here.
The trim cover of the Chiron Sport covers four tailpipes of the six-branch exhaust system at the rear, offering not just visual benefits but technical advantages, too: with its large and sturdy tubes, it helps conduct the waste heat from the hot exhaust gases away from the rear so that no heat accumulation occurs. With 1,500 PS and a top speed of up to 420 km/h, it is these details that make the car a genuine Bugatti and a perfect hyper sports car. Another advantage: at 2.2 kilograms, the printed part weighs 800 grams less than a normal cover. True to Ettore Bugatti's motto “weight is the enemy”, Bugatti always looks at each individual component to find ways to reduce weight.
3D printing offers several advantages
With 3D printing carried out using a special laser printing system, one or more lasers successively melt a thin layer of powder with a thickness of three to four µ. “The advantage of the 3D printing process lies in the geometric shapes that are possible. It is possible to create very finely wrought, complex forms which would tear if made using other techniques such as forging or forming,” says Nils Weimann. This is an ideal production method for Bugatti: there are no tool costs, production is comparatively fast and individual adjustments to the shape are easily possible. As a result, organic geometries can be developed as if from the world of plants – there are virtually no limits.
It takes several days to print the exhaust trim cover. After printing with the material Inconel® 718, material testers scan the component in a computer tomograph (CT) to detect any misprints with air inclusions. In the case of the titanium printing for the Chiron Pur Sport and Chiron Super Sport 300+, test engineers measure the component optically using the 3D process. Thanks to the extremely thin-walled design, air inclusions of any relevant size can already be detected on the outside. The cover blank of the Chiron Sport is then finely blasted with corundum and elegant protection is applied in the form of a high-temperature black ceramic paint finish. The titanium trim covers of the Chiron Pur Sport and Super Sport 300+ retain their elegant matt titanium look. Every component undergoes another check – only perfect trim covers are then fitted.
With the new trim covers, the exhaust systems of the hyper sports cars acquire even more harmonious contours, a more elegant design, and functional styling – all in keeping with the ideology of Ettore Bugatti:
An automobile component must be technically perfect. But it must be elegant and beautiful, too.