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Journal Article

Citation

Nagasaka K, Mizuno K, Ito D, Saida N. Traffic Injury Prev. 2017; 18(Suppl 1): S79-S84.

Affiliation

Nagoya University , Aichi , Japan.

Copyright

(Copyright © 2017, Informa - Taylor and Francis Group)

DOI

10.1080/15389588.2017.1296957

PMID

28318313

Abstract

OBJECTIVE: In car crashes, the passenger compartment deceleration influences the occupant loading significantly. Hence, it is important to consider how each structural component deforms in order to control the passenger compartment deceleration. In frontal impact tests, the passenger compartment deceleration depends on the energy absorption property of the front structures. However, at this point in time there are few papers describing the component's quantitative contributions on the passenger compartment deceleration. Generally, the cross-sectional force is used to examine each component's contribution on the passenger compartment deceleration. However, it is difficult to determine each component's contribution based on the cross-sectional forces, especially within segments of the individual members itself such as the front rails, because the force is transmitted continuously and the cross-sectional forces remain the same through the component.

METHOD: The deceleration of a particle can be determined from the derivative of the kinetic energy. Using this energy-derivative method, the contribution of each component on the passenger compartment deceleration can be determined. Using finite element (FE) car models, this method was applied for full-width and offset impact tests. This method was also applied to evaluate the deceleration of the powertrain. The Finite Impulse Response (FIR) coefficient of the vehicle deceleration (input) and the driver chest deceleration (output) was calculated from JNCAP tests. These were applied to the component's contribution on the vehicle deceleration in FE analysis, and the component's contribution to the deceleration of the driver's chest was determined.

RESULT: The sum of the contribution of each component coincides with the passenger compartment deceleration in all types of impacts; therefore the validity of this method was confirmed. In the full-width impact, the contribution of the crush box was large in the initial phases, and the contribution of the passenger compartment was large in the final phases. For the powertrain deceleration, the crush box had a positive contribution and the passenger compartment had a negative contribution. In the offset test, the contribution of the honeycomb and the passenger compartment deformation on the passenger compartment deceleration was large. Based on the FIR analysis, the passenger compartment deformation contributed the most to the chest deceleration of the driver dummy in the full-width impact.

CONCLUSIONS: Based on the energy-derivative method, the contribution of the components' deformation on the deceleration of the passenger compartment can be calculated for various types of crash configurations more easily, directly and quantitatively than conventional methods. In addition, by combining the energy-derivative method and FIR, each structure's contribution to the occupant deceleration can be obtained. The energy-derivative method is useful in investigating how the deceleration develops from component deformations, and also in designing deceleration curves for various impact configurations.


Language: en

Keywords

Acceleration control; Crashworthiness; Finite Element method; Finite Impulse Response; Front impact; Vehicle design

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