Masanobu Fukushima

Aggressivity-Reducing Structure of Large Vehicles in Side Vehicle-to-Vehicle Crash

Driver fatality rate of a passenger vehicle is considerably high when struck on the side by an LTV (light truck and van). Aggressivity of LTVs, particularly in side crashes, needs to be reduced to improve this incompatible situation. Crash energy absorption share of a passenger car struck on the side by an LTV was measured through component tests. As a result, B-pillar of the struck passenger car was found to receive most of the crash energy intensively. This intensive energy triggered large B-pillar deformation. Computer simulation proved that B-pillar deformation was closely related to occupant injury. The key to mitigate the injury of side-struck car occupant, therefore, is to disperse crash energy to other structural parts than B-pillar. Front-end structures of LTVs that realize crash energy dispersion were designed and examined. The structures include (a) optimization of the vehicle height, and (b) adoption of a forward-extended sub-frame. The aggressivity-reducing effects were confirmed by computer simulation. The aggressivity-reducing structures were found effective in frontal impact as well. The effect was confirmed by using the aggressivity parameters, i.e., Coefficient of Variance and Average Height of Force in vehicle-to-barrier full frontal impact simulation.

Aggressivity-Reducing Structure for Large Vehicles in Frontal Car-to-Car Crash

This paper clarifies aggressivity reduction approach for MPV, Multi-Purpose Vehicles, derived from large passenger vehicles toward small passenger vehicles. The effects of aggressivity-reducing approach were measured through full-frontal rigid barrier crash simulations with TRL aluminum honeycomb by Finite Element Method. The front-end structures of large vehicles studied in this paper based on this aggressivity reduction approach show good front-end homogeneity and low average height of force. The structures were also found to effectively reduce aggressivity toward small vehicles by car-to-car simulation. However, there are some cases where the effect was influenced by overlap ratios. From this result, overlap ratio is considered to be one of the important factors to improve compatibility performance.

Effect of subframe structure on compatibility performance

With an aim to improve compatibility performance, vehicle-to-vehicle frontal impact simulations have been conducted between large car and small car. Focusing on sub-frame structure that disperses applied force with multiple load paths, a large saloon car with sub-frame was selected and three different front structures were studied: original, forward-extended sub-frame, and original with 25%-stiffness reduced structures. The types of collision contained four different crash modes in a combination of lateral overlap rate difference and side member height difference. As a result, it was found that the front structure with forward-extended sub-frame improved aggressivity by preventing interaction enhancement. Height of Force (HOF) was also improved. (A) For the covering abstract see ITRD E121867.