Impact energy and the risk of injury to motorcar occupants in the front-to-side vehicle collision

Prochowski, Leon; Ziubiński, Mateusz; Dziewiecki, Krzysztof; Szwajkowski, Patryk

doi:10.1007/s11071-022-07779-8

Cited by 5 publications

(4 citation statements)

References 33 publications

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“…Research has found that left OOP reduces the severity of driver injuries, Xu Zhe [11] studied the forward disengagement of occupants caused by the AEB system, and Mages [16] showed that this disengagement increases occupant injuries, so we believe that excessive disengagement will cause the driver to come into contact with the door or the B-pillar, which will increase the risk of driver injuries, and that, in addition to the improvement of the AES system, it is necessary to match the active pre-tensioning seat belts with the side airbags to protect the driver; More serious damage occurred when the collision area was the B-pillar, and Leon [28] also indicated that contact with the B-pillar caused the most serious damage in a side impact; At impact angle of 60°, the abdominal combined force was found to exceed the threshold and the severity of injury was higher, so we suggest that improvements to the AES need to be made to avoid the B-pillar and impact angles of 60° as much as possible. With active pre-tensioning seat belts, lateral OOP of all parts of the driver was reduced, and driver injuries were reduced compared to normal seat belts.…”

Section: Ivdiscussionmentioning

confidence: 99%

Driver Injury During Automatic Emergency Steering in Vehicle–Vehicle Side-Impact Collisions

Zhang,

Li,

Lei

et al. 2024

IEEE Access

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Section: Ivdiscussionmentioning

confidence: 99%

Driver Injury During Automatic Emergency Steering in Vehicle–Vehicle Side-Impact Collisions

Zhang,

Li,

Lei

et al. 2024

IEEE Access

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“…In the first phase of motion, the car has moved with relative transverse friction between the tires and the road surface, and the motion trajectory is arc-shaped. The car has crossed the entire traffic lane diagonally and what follows is an impact into the roadside tree (Figures 1 and 2) [13][14][15][16]. of mass of the car coordinate system, symmetrically located with respect to the car body.…”

Section: Dynamic Model Of a Vehicle-fixed Barrier Front Crashmentioning

confidence: 99%

“…In the first phase of motion, the car has moved with relative transverse friction between the tires and the road surface, and the motion trajectory is arc-shaped. The car has crossed the entire traffic lane diagonally and what follows is an impact into the roadside tree (Figures 1 and 2) [13][14][15][16]. As long as the kinematic quantities in the motion phases are known, it would be possible to sufficiently predict the magnitudes and directions of each component of the inertial forces, including the magnitude of the resultant vector sum.…”

Section: Dynamic Model Of a Vehicle-fixed Barrier Front Crashmentioning

confidence: 99%

Impact of Inertial Forces on Car Occupants in a Vehicle-Fixed Barrier Front Crash

Karapetkov,

Uzunov,

Dechkova

et al. 2023

Symmetry

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In most cases, the dynamic investigation of vehicle collisions with stationary obstacles concerns solutions to complex tasks related to the identification of occupant position in the vehicle. The motion of the bodies in the car is determined by the intensity of the inertial coordinate system, also known as moving reference frame, invariably fixed to the vehicle’s center of mass. The focus of the study is on how forces of inertia change their magnitude and direction in the car’s motion. This requires specific analysis carried out by dividing the vehicle trajectory into separate stages according to certain indicators, such as free motion, impact process, and post-impact residual motion. Particular attention has been paid to the impact itself, in which the forces of inertia are the most intense, and their magnitude and direction change abruptly. A solution to a Cauchy problem has been found, in which initial kinematic parameters of the crash process are considered, satisfying the kinematic values at rest position.

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“…The crashworthiness requirements mainly involved about 44 rules in FAR 25, and were mainly distributed in subparts C, D, E, F and G [32][33][34], such as Section 25.561 "General" and Section 25.562 "Emergency landing dynamic conditions", which emphasizing that the aircraft structure design must protect each occupant during an emergency landing condition, and provide the dynamic conditions for the seat design. Many impact sled tests had been conducted to evaluate the occupant injury, and many correlated studies of analytical simulations with impact sled test results had also been accomplished [35][36][37]. Therefore, a series of guidance documents had been formed for the verification and certification of aircraft crashworthiness and occupant safety.…”

Section: Introductionmentioning

confidence: 99%

Crash response and occupant injury analysis in vertical drop test of a typical large transport aircraft fuselage section

Feng,

Mou

2024

Preprint

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To analyze the crash characteristics of a typical large aircraft fuselage section and occupant injury, a three-frame typical fuselage section was designed and fabricated, which including two sets of triple seats and four 50th-percentile FAA Hybrid III Anthropomorphic Test Devices (ATDs). The vertical drop test of fuselage section was conducted at 6.02m/s, the crash response and occupant injury were analyzed, and the crashworthiness evaluation and analysis of fuselage section were further conducted. The results show that the sub-cabin floor structures suffer the serious deformation and damage, which is the unrolling failure mode (three plastic hinges failure mode), and one opening plastic hinge is generated in the sub-cargo middle support columns area, and two opening plastic hinges are generated in the connection areas between the both sides cabin floor support columns and fuselage frames. The cabin area is remained basically intact, and the survivable volume is maintained. The connections between the seats and cabin floor guide rails are maintained in good condition, and the occupant seat belts are kept in place. The maximum value of head injury criterion and lumbar spine compression load are 31.47 and 3997.2 N, respectively, which are much lower than the threshold of Airworthiness Standard. The ATDs lean towards the aisle, and the occupant egress paths are maintained. The aircraft crashworthiness is evaluated by considering the survivable volume, retention strength, occupant injury and emergency evacuation, and the Integrated Crashworthiness Index (ICI) is used to evaluate the aircraft crashworthiness by the scoring method, which indicating a low occupant injury risk. The flattening failure mode (multiple plastic hinges failure mode) of fuselage section can be realized by controlling the failure load, failure position and failure sequence of fuselage section, and more crash energy can be absorbed by producing multiple plastic hinges of fuselage section, which can effectively improve the crashworthiness of fuselage section.

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Impact energy and the risk of injury to motorcar occupants in the front-to-side vehicle collision

Cited by 5 publications

References 33 publications

Driver Injury During Automatic Emergency Steering in Vehicle–Vehicle Side-Impact Collisions

Driver Injury During Automatic Emergency Steering in Vehicle–Vehicle Side-Impact Collisions

Impact of Inertial Forces on Car Occupants in a Vehicle-Fixed Barrier Front Crash

Crash response and occupant injury analysis in vertical drop test of a typical large transport aircraft fuselage section

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