Can emergency avoidance behavior reduce injuries to electric two-wheeler riders in vehicle collisions?

Abstract Objectives The aim of this study was to examine the effects of emergency avoidance behaviors on the kinematics and injuries of electric two-wheeler (ETW) riders. Methods Four typical riding postures of ETW riders before collisions, including one normal posture and three avoidance postures, were identified through analysis of 298 videos of vehicle to ETW accidents. Crash simulations were then performed using the Total Human Model of Safety (THUMS) occupant model, ETW and a sedan finite element (FE) model, and the kinematics of ETW riders were compared. The risk of head injury and lower extremity injury was also investigated. Results When the struck foot position of the ETW rider was lower than the ETW pedal, the lower extremity was struck by the sedan bumper and ETW frame from the right and left side respectively, and the upper body of the rider rotated around the hood leading edge. At a car velocity of 40 km/h, the rider was at high risk of head injury and the tibia was fractured. The medial cruciate ligament (MCL) was ruptured in both the 20 km/h and 40 km/h collisions. When the struck foot position of the ETW rider was higher than the pedal, the lower extremity was hit by the bumper and then rebounded. In this situation, the bending moments of the femur and tibia, as well as the bending angle and shear displacement of the knee joint were less than the injury threshold in all crash simulations. Furthermore, when the head was turned toward the colliding car, the risk of head injury varied with the emergency avoidance posture. Conclusions The height of the struck foot relative to the ETW pedal influenced the rider’s global kinematics, and head and lower extremity injuries risk. In the struck side foot landing and both feet landing postures, the lower extremity was restrained and compressed by the ETW frame, resulting in a high risk of tibia fracture and MCL rupture. Reducing the impact velocities could effectively mitigate the injury risk of the ETW riders; however, loading patterns remain an important factor influencing the risk of lower extremity injury.

[1]  Bingbing Nie,et al.  Kinetic and Kinematic Features of Pedestrian Avoidance Behavior in Motor Vehicle Conflicts , 2021, Frontiers in Bioengineering and Biotechnology.

[2]  Hongwu Huang,et al.  Study of typical electric two-wheelers pre-crash scenarios using K-medoids clustering methodology based on video recordings in China. , 2021, Accident; analysis and prevention.

[3]  Zhonghao Bai,et al.  A study on the cyclist head kinematic responses in electric-bicycle-to-car accidents using decision-tree model. , 2021, Accident; analysis and prevention.

[4]  Liangliang Shi,et al.  Helmet protective performance via reconstruction of electric two-wheeler rider’s head-to-ground impact accidents , 2020, International Journal of Crashworthiness.

[5]  Xiaojiang Lv,et al.  Head kinematics study of E-bicycle rider in car to E-bicycle side collisions , 2020 .

[6]  Wei He,et al.  Effect of vehicle steering maneuvers on kinematics and head injury risks of cyclists via finite element modeling analysis , 2020, International Journal of Crashworthiness.

[7]  Bingbing Nie,et al.  Are riders of electric two-wheelers safer than bicyclists in collisions with motor vehicles? , 2019, Accident; analysis and prevention.

[8]  Koji Mizuno,et al.  Analysis of pedestrian-to-ground impact injury risk in vehicle-to-pedestrian collisions based on rotation angles. , 2018, Journal of safety research.

[9]  Koji Mizuno,et al.  The influence of lower extremity postures on kinematics and injuries of cyclists in vehicle side collisions , 2016, Traffic injury prevention.

[10]  Jikuang Yang,et al.  The influence of gait stance on pedestrian lower limb injury risk. , 2015, Accident; analysis and prevention.

[11]  Thomas Robert,et al.  Observations on pedestrian pre-crash reactions during simulated accidents. , 2013, Stapp car crash journal.

[12]  Koji Mizuno,et al.  A study on chest injury mechanism and the effectiveness of a headform impact test for pedestrian chest protection from vehicle collisions , 2012 .

[13]  Pierre Jean Arnoux,et al.  Finite element analysis of cyclist lower limb response in car—bicycle accident , 2006 .

[14]  W. Sinz,et al.  Extracting Quantitative Descriptions of Pedestrian Pre-crash Postures from Real-world Accident Videos , 2020 .

[15]  Daisuke Ito,et al.  Finite element analysis of kinematic behavior of cyclist and performance of cyclist helmet for human head injury in vehicle-to-cyclist collision , 2014 .