Megatrends in the automotive industry are posing new challenges for the materials used, yet at the same time opening up new opportunities. Electromobility and autonomous driving are set to revolutionize cars and put established vehicle concepts to the test.
|Future mobility is set to revolutionize the interior of vehicles, and beyond.|
Automobile trends, such as reduced emissions, electrification and automated driving, will only become a reality with constant innovation. Modern vehicles already rely heavily on material solutions from the plastics industry; however, in the future, chemistry will play an even greater role, making a significant contribution to solving tomorrow’s mobility challenges.
The speed at which the industry is able to optimize the performance, weight, safety and above all the efficiency of electric drive trains will be a crucial factor in the success of electromobility. Flame-retardant plastics are indispensable in enabling savings to be made in terms of the weight and installation space required for high-voltage components. Special polyamide (PA) and polybutylene terephthalate (PBT) grades from BASF can be used as halogen-free, flame-retardant materials to give high-voltage components both inside and outside of the vehicle the exact properties required. These engineering plastics meet the highest requirements in flame retardance, color stability, mechanics, and electric insulation.
At the same time, the intrinsic insulating properties add to the safety in the vehicle. BASF has a portfolio of various PA 6 and 66 grades available to ensure dependable microelectronics in control equipment and sensors that help prevent electric corrosion damage to circuits. The various Ultramid EQ grades (EQ: electronic quality) that BASF has been marketing for years are extremely pure and contain almost no electrically active or corrosive substances, such as halides. Furthermore, this material also has excellent heat aging resistance properties.
Today’s electronic drive systems are still primarily part of the metals industry. Top date, manufacturers of electronic motors and power electronic components have been using housing made of steel or die-cast aluminum. As many of the components are now actively cooled, meaning that heat no longer needs to be dissipated via the housing, plastic solutions are now a possibility for lightweight construction, for example flame-retardant Ultramid grades A3U42G6 and B3U50G6.
Housings that contain high-voltage electric components must be electrically shielded to prevent compromising the surrounding area. Metal coatings on the plastic housing parts are one of the possible solutions that BASF is pursuing. Coating in this way can provide good shielding of the magnetic field. In addition, engineering plastics offer the advantage of integrating additional functions into the component. In prototype pre-series projects with customers, it has already been able to show that plastic housings manufactured using this process are lighter and more economical than comparable die-cast aluminum housings.
In addition to electromobility, highly automated driving will also revolutionize tomorrow's vehicles. In driverless vehicles, the interior will become an extended living room. The number of sensors will increase significantly, relieving drivers of many driving tasks. BASF has already made a significant contribution to a number of sensitive electronic sensor technologies with its unique portfolio of hydrolytically resistant PBT grades.
However, the increasing level of automation will also see a range of new sensors, such as radar, lidar, IR, and ultrasonic sensors find their way into our cars. These function not only as lane assistants but also as collision warning systems and distance controllers, and also assist with the emergency brake function – a basic prerequisite for controlling cars completely automatically in the future. Implementing these solutions into large-scale production can only be guaranteed using plastics.
BASF also offers radar-optimized plastics used for radar transmission and absorption that increase the accuracy of the radar sensors, thereby improving the functionality of the automated vehicle with greater cost efficiency.