Assessment of bicycle–car accidents under four different types of collision

Raslavičius, Laurencas; Bazaras, Liudas; Keršys, Artūras; Lukoševičius, Vaidas; Makaras, Rolandas; Eidukynas, Valdas

doi:10.1177/0954411917690417

Cited by 14 publications

(8 citation statements)

References 14 publications

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“…It can be explained due to the different geometry between the fronts of the vehicles used because the cyclist's head hits a higher area of the windshield at this speed, which has a higher stiffness, which significantly increases HIC. On the other hand, Raslavicius et al use a multibody solver, while this work uses a finite element model that can make specific differences in body deformations in contact during impact [7]. The results obtained are steady with the severity of the literature's injuries by agreeing that this crash scenario generates severe or fatal injuries [8,28].…”

Section: Discussionmentioning

confidence: 67%

“…The Pedestrian and Bicycle Crash Analysis Tool (PBCAT) distinguishes around 79 scenarios that consider different factors such as the vehicle's position before the impact, the direction in which one respects the other, and the impact causes [6]. The scenario reported a greater probability of cyclist death, where the motor vehicle is moving in the same direction as the cyclist and the bicycle is reached in the rear side by the front of the car; this scenario is called the overtaking scenario [7,8]. Also, in National Highway Traffic Safety Administration (NHTSA) in the database called Fatality Analysis Reporting System (FARS) from 2008 to 2012, the crash scenario that presented the highest death rate of the cyclist in the United States is the overtaking crash scenario [9], repeating this trend in subsequent years until 2017, which is the last update.…”

Section: Introductionmentioning

confidence: 99%

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Numerical Assessment of a Safety System to Minimize Injuries during a Cyclist Run-Over

López-García

Carbajal-Romero

Flores-Campos

et al. 2021

Applied Bionics and Biomechanics

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Background. The World Health Organization has reported that 1.35 million people die on the roads every year due to road traffic accidents. This paper focuses on exploring a passive safety system that reduces lesions in the overtaking run-over scenario. Methods. Head Injury Criterion (HIC) and Combined Thoracic Index (CTI) were evaluated through numerical simulations using LS-Dyna®; in order to compare the computed results, three different speed scenarios were carried out (velocity of running over 40, 50, 60 km/h). Results. The computed results were divided into groups, A for the run-over test without a passive security system and B for the run-over test with a passive security system. For case A.1, the HIC15 was 3325. For case A.2, the HIC15 was 1510, and for case A.3, the HIC 15 was 1208. For case B.1, the HIC15 2605, for case B.2, the HIC15 was 1282, and for case B.3, the HIC was 730. Conclusion. The comparative results show that the passive safety system installed on the bicycle has an increased benefit impact on the severity of the injury on vulnerable road users, decreasing the probability of cranioencephalic lesions in all study cases. In addition, the thorax injuries are cut down only in the impact scenario at a speed of 40 km/h.

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Section: Discussionmentioning

confidence: 67%

Section: Introductionmentioning

confidence: 99%

Numerical Assessment of a Safety System to Minimize Injuries during a Cyclist Run-Over

López-García

Carbajal-Romero

Flores-Campos

et al. 2021

Applied Bionics and Biomechanics

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“…Raslavicius et al 5 studied bicycle–car accidents under four different types of collision and concluded that it is very important to mitigate head and neck impact to the windscreen of the car. If so, a dominant share of fatal cyclist crashes and severe traumatic head injury cases at collision speeds exceeding 40 km/h could be prevented.…”

Section: Introductionmentioning

confidence: 99%

Head kinematics study of E-bicycle rider in car to E-bicycle side collisions

Zhang

et al. 2020

Proceedings of the Institution of Mechanical Engineers, Part D:

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In recent years, car to bicycle collisions take place more and more frequently, which have attracted the attention of some organizations and engineers. They are trying to make some rules for cars to realize better bicyclist protection, including defining new head impact location area and head impact velocity in pedestrian protection tests. However, car to E-bicycle collisions occur more than car to bicycle collisions in China. Therefore, vehicle to E-bicycle collisions should be researched to define appropriate head impact location area and head impact velocity in pedestrian protection tests for cars in Chinese market. In this article, the head kinematics of E-bicycle riders in car to E-bicycle side collisions are studied. First, through analyzing data from China In-Depth Accident Study Database (which conducts field investigation, analysis, and research on traffic accidents in China), some representative conditions and key parameters in car to E-bicycle collisions are extracted. Second, a condition of car to E-bicycle side collision from above analysis is simulated. Third, an experiment according to the above condition is performed and the finite element models in the above simulation are validated. Then, a series of conditions are simulated by using the validated models, and some factors affecting head impact locations and head impact velocities in car to E-bicycle side collisions are studied. Finally, some factors that affect the head kinematics of E-bicycle riders in car to E-bicycle collisions are identified and some results of head movement in these collisions are concluded, such as head impact locations and head impact velocities.

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“…When only factors like impact position and vehicle speed are considered in the study, establishing a verified numerical simulation model is a better approach to do the research. [36][37][38] By establishing a verified numerical simulation model, Raslavicˇius et al 39 studied the effects of factors like impact location and direction on injury severity of the bicycler. The aim of this article is to investigate the influences of various factors, most of which are categorical variables, on fatality of the driver.…”

Section: Introductionmentioning

confidence: 99%

An investigation on fatality of drivers in vehicle–fixed object accidents on expressways in China: Using multinomial logistic regression model

Peng

Wang

et al. 2018

Proc Inst Mech Eng H

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This study aims to identify the effects of characteristics of vehicle, roadway, driver, and environment on fatality of drivers in vehicle-fixed object accidents on expressways in Changsha-Zhuzhou-Xiangtan district of Hunan province in China by developing multinomial logistic regression models. For this purpose, 121 vehicle-fixed object accidents from 2011-2017 are included in the modeling process. First, descriptive statistical analysis is made to understand the main characteristics of the vehicle-fixed object crashes. Then, 19 explanatory variables are selected, and correlation analysis of each two variables is conducted to choose the variables to be concluded. Finally, five multinomial logistic regression models including different independent variables are compared, and the model with best fitting and prediction capability is chosen as the final model. The results showed that the turning direction in avoiding fixed objects raised the possibility that drivers would die. About 64% of drivers died in the accident were found being ejected out of the car, of which 50% did not use a seatbelt before the fatal accidents. Drivers are likely to die when they encounter bad weather on the expressway. Drivers with less than 10 years of driving experience are more likely to die in these accidents. Fatigue or distracted driving is also a significant factor in fatality of drivers. Findings from this research provide an insight into reducing fatality of drivers in vehicle-fixed object accidents.

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Assessment of bicycle–car accidents under four different types of collision

Cited by 14 publications

References 14 publications

Numerical Assessment of a Safety System to Minimize Injuries during a Cyclist Run-Over

Numerical Assessment of a Safety System to Minimize Injuries during a Cyclist Run-Over

Head kinematics study of E-bicycle rider in car to E-bicycle side collisions

An investigation on fatality of drivers in vehicle–fixed object accidents on expressways in China: Using multinomial logistic regression model

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