Researchers at Chalmers University of Technology, in Sweden, have developed a new truck front concept to significantly reduce fatal crashes in car-truck collisions.
The new truck front comes after the EU regulations for the maximum length of a truck were lifted. Crash tests on the new truck front were carried out by the Swedish Transport Administration, Trafikverket, and show that better truck designs can reduce passenger car compartment deformations by 30-60 percent. This reduces the risk of injury and possible death for the car occupants.
(above) Test with truck front.
(above) Test without truck front.
Fatal crashes between heavy goods vehicles (HGVs) and passenger cars account for between 14 to 16 percent of all car occupant fatalities in both the EU and US. In over 90 percent of traffic accidents involving HGVs it is the other party who dies, usually in a passenger car. The most common accident types in these collisions are head-on crashes on rural roads and rear-end crashes on highways (the HGV drives into the rear of the car in front). It is therefore important to investigate car-to-HGV crashes further to improve the survival rates of passengers in the cars of such collisions.
A truck front designed to not kill
It is widely accepted that two modern passenger cars of the best safety standards should be able to cope with a collision, 80 kilometres per hour, without fatal consequences. This is not the case for collisions between trucks and cars. Whilst the velocity is often moderate in truck-car collisions, the crash severity is still high due to geometry, stiffness, and mass incompatibility between the two vehicles.
In order for a passenger car occupant to survive a head-on collision with a truck, the cabin in the passenger car needs to be kept intact. This is not something that is possible to guarantee today, even in the most modern cars, so the new truck front research aims to find the best ways to protect car passengers, as well as truck drivers, in the future.
Cars and trucks have discrete structural elements (bumpers, energy absorbing beams, passenger compartment frames) that are designed to deform and absorb energy or remain intact and protect occupants. It has been observed in real-world crashes that these localised structures rarely interact the way they were designed. This leads to a less efficient crash response. A team of researchers at Chalmers University of Technology designed a truck front that would improve the collision process. This latest design was based on earlier research carried out at Chalmers.
“We know that providing a distributed force over the struck car would allow its crash structures to perform more efficiently. From the first test, we could also see that the energy levels observed were high and better energy absorption by the truck was needed. Another challenge was also trying to direct the car away from the truck’s forward path”, says Professor Robert Thomson, Division of Vehicle Safety at Chalmers University of Technology.
New EU regulations allow for change
The new front was designed with the goal to demonstrate potential design principles to be interpreted and adapted by manufacturers.
“The internal design of the new truck front is aluminium honeycomb. This is a structure composed of repeating hexagonal tubes made from aluminium foil. This is ideal for a lightweight, energy absorbing structure, since around 97 percent of its volume is air. Aluminium honeycomb is used in many crash test barriers to provide a distributed force and absorb energy. By changing the foil thickness, we can change the force and deformation characteristics. It also has the manufacturing flexibility needed to create “one-of” prototypes and demonstrate “proof-of-concept”, says Professor Thomson.
One of the main contributions was to take advantage of the new truck dimension regulations in Europe that were amended in 2019 (Decision (EU) 2019/984). This relaxed the previous maximum limit to a truck combination length which led to “flat front” trucks in Europe that maximised cargo space on a truck within a fixed length. This resulted in limited design space and little opportunity to integrate crashworthiness designs, like those found in passenger cars, in trucks.
Unique tests show 30-60 percent less impact in crash
The new truck front was tested by The Swedish Transport Administration, Trafikverket, at the Autoliv test track in Vårgårda, in a set of unique tests. The tests showed measurable results and clearly highlighted that the new truck front made a big difference. The crash tests show that better truck designs can reduce passenger car compartment deformations by 30-60 percent, which reduces the risk of injury for the car occupants. Deformation of the truck was also reduced in sensitive areas and improved truck driver safety and cargo security. Steering, braking, and suspension components are at risk to be damaged if not protected. Protecting these components reduces the risk for subsequent crashes or even rollovers of the truck.
“A truck is involved in every fifth fatal accident in road traffic. Despite the fact that trucks only account for 6 percent of the traffic volume in Sweden where the tests were carried out, around 45 people die a year in traffic accidents involving heavy trucks, and in over 90 percent of these it is the other party who dies, usually in a passenger car.The goal is to develop a standard for crash tests for trucks that can be introduced in Euro NCAP's consumer tests in 2030. We want the people in a passenger car to be able to survive a head-on collision with a truck because the car compartment remains intact”, says Rikard Fredriksson, Senior Advisor at Trafikverket and Adjunct Professor at Chalmers.
The test was based on a modern passenger car and heavy truck crashing at speeds that would result in a fatal accident. The crash test was run at 50 kilometres per hour but simulates an original travel speed of 80 that is reduced by 30 kilometres per hour by automatic emergency braking systems (AEB) that are required in newer cars and trucks.
Chalmers University of Technology, The Swedish Transport Administration, and the automotive industry are working together to further develop the tests with the truck front.
Previous research and background information:
Truck front research: From Chalmers University of Technology, Professor Robert Thomson was assisted by Mobility Master’s Students project groups in 2022 and 2023. Krystoffer Mroz from Autoliv Research was also involved with the front structure design providing simulation expertise.
Previous crash tests: The first truck-car crash test demonstrated how the loading between the two vehicles was focused on a few structures that were overloaded and created undesired deformation in the surrounding structures. For the car it was the left front wheel and the driver’s door area and for the truck it was the suspension and steering system. The new truck front design improved the force distribution and reduced the local deformation.
European New Car Assessment Programme, best known as Euro NCAP, is an organisation that rates the safety of new vehicles in Europe. The company was first established in 1997 for the UK’s Department for Transport, with the aim of performing independent security tests on new cars but was later backed by most European countries. Now, the company provides the most reliable reviews and ratings regarding new vehicles’ safety, and their tests over the years have resulted in improved standards.
Tests being carried out in Sweden: In 1997 the Swedish parliament adopted a vision that nobody would get killed in traffic - Vision Zero - and since then the road fatalities have been reduced by almost two thirds. Sweden currently has a fatality rate of 1.9 road fatalities per 100,000 inhabitants in 2020. Together with Norway, this is the lowest traffic fatality rate in the world. Vision Zero anticipates that people make mistakes, so the transport system should be designed using biomechanical limits. This facilitates an environment where crashes involving safe vehicles, safe infrastructure, and safe road users won’t produce fatal or severely injured individuals.