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Author: Yong Peng Publisher: ISBN: Category : Languages : en Pages : 0
Book Description
Pedestrians are regarded as an extremely vulnerable and high-risk group of road users since they are unprotected in vehicle impacts. More than 1.17 million people throughout the world are killed in road traffic accidents each year. Where, about 65% of deaths involve pedestrians. The head injuries in vehicle-pedestrian collisions accounted for about 30% of all reported injuries on different body regions, which often resulted in a fatal consequence. Such injuries can result in disabilities and long-term sequence, which lead to significant social costs. It is therefore important to study the characteristics of pedestrian accidents and understand the head injury mechanism of the pedestrian so as to improve vehicle design for pedestrian protection. The aim of this study is to investigate pedestrian dynamic response and develop head injury risk functions.In order to investigate the effect of pedestrian gait, vehicle front geometry and impact velocity on the dynamic responses of the head, the multi-body dynamic (MBD) models were used to simulate the head responses in vehicle to pedestrian collisions with different vehicle types in terms of head impact point measured with Wrap Around Distance (WAD), head relative velocity and impact angle. A simulation matrix is established using five vehicle types, and two mathematical models of the pedestrians represented a 50th male adult and a 6 year old child as well as seven pedestrian gaits based on typical postures in pedestrian accidents. In order to simulate a large range of impact conditions, four vehicle velocities (30 km/h, 40 km/h, 50 km/h and 60 km/h) are considered for each pedestrian position and vehicle type.A total of 43 passenger car versus pedestrian accidents were selected from In-depth Investigation of Vehicle Accidents in Changsha, China (IVAC) and German In-Depth Accident Study (GIDAS) database for simulation study. According to real-world accident investigation, accident reconstructions were conducted using multi-body system (MBS) pedestrian and car models under MADYMO simulation environment to calculate head impact conditions, in terms of head impact velocity, head position and head orientation. In order to study kinematics of adult pedestrian, relationship curves: head impact time, throw distance, head impact velocity and vehicle impact velocity, were computed and logistic regression models: head impact velocity, resultant angular velocity, HIC value, head contact force and head injuries, were developed based on the results from accident reconstructions.The automobile windshield, with which pedestrians come into frequent contact, has been identified as one of the main contact sources for pedestrian head injuries. In order to investigate the mechanical behavior of windshield laminated glass in the caseof pedestrian head impact, windshield FE models were set up using different combination for the modeling of glass and PVB, with various connection types and two mesh sizes (5 mm and 10 mm). Each windshield model was impacted with a standard adult headform impactor in an LS-DYNA simulation environment, and the results were compared with the experimental data reported in the literatures.In order to assess head injury risks of adult pedestrians, accident reconstructions were carried out by using Hybrid III head model based on the real-world pedestrian accidents. The impact conditions were obtained from the MBS simulation, including head impact velocity, head position and head orientation. They were used to set the initial conditions in a simulation of a Hybrid III FE head model striking a windshield FE model. Logistic regression models, Skull Fracture Correlate (SFC), head linear acceleration, Head Impact Power (HIP), HIC value, resultant angular acceleration and head injuries, were developed to study brain injury risk.{...].
Author: Yong Peng Publisher: ISBN: Category : Languages : en Pages : 0
Book Description
Pedestrians are regarded as an extremely vulnerable and high-risk group of road users since they are unprotected in vehicle impacts. More than 1.17 million people throughout the world are killed in road traffic accidents each year. Where, about 65% of deaths involve pedestrians. The head injuries in vehicle-pedestrian collisions accounted for about 30% of all reported injuries on different body regions, which often resulted in a fatal consequence. Such injuries can result in disabilities and long-term sequence, which lead to significant social costs. It is therefore important to study the characteristics of pedestrian accidents and understand the head injury mechanism of the pedestrian so as to improve vehicle design for pedestrian protection. The aim of this study is to investigate pedestrian dynamic response and develop head injury risk functions.In order to investigate the effect of pedestrian gait, vehicle front geometry and impact velocity on the dynamic responses of the head, the multi-body dynamic (MBD) models were used to simulate the head responses in vehicle to pedestrian collisions with different vehicle types in terms of head impact point measured with Wrap Around Distance (WAD), head relative velocity and impact angle. A simulation matrix is established using five vehicle types, and two mathematical models of the pedestrians represented a 50th male adult and a 6 year old child as well as seven pedestrian gaits based on typical postures in pedestrian accidents. In order to simulate a large range of impact conditions, four vehicle velocities (30 km/h, 40 km/h, 50 km/h and 60 km/h) are considered for each pedestrian position and vehicle type.A total of 43 passenger car versus pedestrian accidents were selected from In-depth Investigation of Vehicle Accidents in Changsha, China (IVAC) and German In-Depth Accident Study (GIDAS) database for simulation study. According to real-world accident investigation, accident reconstructions were conducted using multi-body system (MBS) pedestrian and car models under MADYMO simulation environment to calculate head impact conditions, in terms of head impact velocity, head position and head orientation. In order to study kinematics of adult pedestrian, relationship curves: head impact time, throw distance, head impact velocity and vehicle impact velocity, were computed and logistic regression models: head impact velocity, resultant angular velocity, HIC value, head contact force and head injuries, were developed based on the results from accident reconstructions.The automobile windshield, with which pedestrians come into frequent contact, has been identified as one of the main contact sources for pedestrian head injuries. In order to investigate the mechanical behavior of windshield laminated glass in the caseof pedestrian head impact, windshield FE models were set up using different combination for the modeling of glass and PVB, with various connection types and two mesh sizes (5 mm and 10 mm). Each windshield model was impacted with a standard adult headform impactor in an LS-DYNA simulation environment, and the results were compared with the experimental data reported in the literatures.In order to assess head injury risks of adult pedestrians, accident reconstructions were carried out by using Hybrid III head model based on the real-world pedestrian accidents. The impact conditions were obtained from the MBS simulation, including head impact velocity, head position and head orientation. They were used to set the initial conditions in a simulation of a Hybrid III FE head model striking a windshield FE model. Logistic regression models, Skull Fracture Correlate (SFC), head linear acceleration, Head Impact Power (HIP), HIC value, resultant angular acceleration and head injuries, were developed to study brain injury risk.{...].
Author: Kyle A. Ott Publisher: ISBN: Category : Head Languages : en Pages : 208
Book Description
Abstract: Pedestrians account for roughly 12% of all motor vehicle related fatalities in the United States, which equates to approximately 4,700 deaths per year. Head injuries are the most common cause of death in these accidents. Current test procedures around the world involve launching a projectile headform into vehicle structures to assess aggressiveness toward pedestrians. The Head Injury Criterion (HIC) uses linear accelerations from a pedestrian headform to assess impact severity, which is in turn dictated by the head impact velocity and vehicle stiffness. Vehicle exterior contours or underhood structures often impart a rotational component to the headform upon impact as well as affecting the wrap around distance (WAD). In the past several years, evidence has indicated that these types of rotational accelerations influence injury. The objective of this study was to examine the relationships between vehicle characteristics and head injury using a combination of computer modeling, experimental testing, and accident data. Analytical tools could then be constructed based on these quantified relationships to facilitate pedestrian-safe vehicle design. A multi-body, finite element-based headform model has previously been developed to exhibit response characteristics consistent with the International Harmonization Research Activities (IHRA) adult and child pedestrian headforms. In the current study, a series of simulations with this model was conducted using a wide range of impact velocities and stiffness values, producing a distribution of HIC values. Experimental test data was used to determine where a sample of the U.S. fleet falls in the simulated HIC matrix. The second phase of this research involved the investigation of head injury mechanisms through case reconstruction. Full-scale pedestrian case reconstructions were done in MADYMO to acquire linear and angular accelerations of the pedestrian's head. These accelerations were then entered into the Simulated Injury Monitor (SIMon) algorithm to predict brain injury based on both translational and rotational acceleration. These predicted injuries were then compared to those documented in the case. The third phase of this study involved the relation of certain accident geometric parameters to injury using statistical software to analyze the Pedestrian Crash Data Study (PCDS) data and derive relations. This would help lead to an equation that would predict probability of brain injury based on certain geometric characteristics. Three different tools were developed from this study. The first tool is a HIC predictive algorithm that gave HIC as a function of head impact velocity and linear stiffness. The second tool is a reconstruction process through which both traumatic brain injury and skull fracture may be predicted. The third tool is a relation between WAD as a function of vehicle impact speed and top transition point normalized by pedestrian height as well as a set of probability curves of injury as a function of vehicle speed.
Author: National Research Council Publisher: National Academies Press ISBN: 0309288037 Category : Medical Languages : en Pages : 215
Book Description
In the past decade, few subjects at the intersection of medicine and sports have generated as much public interest as sports-related concussions - especially among youth. Despite growing awareness of sports-related concussions and campaigns to educate athletes, coaches, physicians, and parents of young athletes about concussion recognition and management, confusion and controversy persist in many areas. Currently, diagnosis is based primarily on the symptoms reported by the individual rather than on objective diagnostic markers, and there is little empirical evidence for the optimal degree and duration of physical rest needed to promote recovery or the best timing and approach for returning to full physical activity. Sports-Related Concussions in Youth: Improving the Science, Changing the Culture reviews the science of sports-related concussions in youth from elementary school through young adulthood, as well as in military personnel and their dependents. This report recommends actions that can be taken by a range of audiences - including research funding agencies, legislatures, state and school superintendents and athletic directors, military organizations, and equipment manufacturers, as well as youth who participate in sports and their parents - to improve what is known about concussions and to reduce their occurrence. Sports-Related Concussions in Youth finds that while some studies provide useful information, much remains unknown about the extent of concussions in youth; how to diagnose, manage, and prevent concussions; and the short- and long-term consequences of concussions as well as repetitive head impacts that do not result in concussion symptoms. The culture of sports negatively influences athletes' self-reporting of concussion symptoms and their adherence to return-to-play guidance. Athletes, their teammates, and, in some cases, coaches and parents may not fully appreciate the health threats posed by concussions. Similarly, military recruits are immersed in a culture that includes devotion to duty and service before self, and the critical nature of concussions may often go unheeded. According to Sports-Related Concussions in Youth, if the youth sports community can adopt the belief that concussions are serious injuries and emphasize care for players with concussions until they are fully recovered, then the culture in which these athletes perform and compete will become much safer. Improving understanding of the extent, causes, effects, and prevention of sports-related concussions is vitally important for the health and well-being of youth athletes. The findings and recommendations in this report set a direction for research to reach this goal.
Author: Marjorie Peden Publisher: DIANE Publishing ISBN: 1437904068 Category : Transportation Languages : en Pages : 67
Book Description
Every day thousands of people are killed and injured on our roads. Millions of people each year will spend long weeks in the hospital after severe crashes and many will never be able to live, work or play as they used to do. Current efforts to address road safety are minimal in comparison to this growing human suffering. This report presents a comprehensive overview of what is known about the magnitude, risk factors and impact of road traffic injuries, and about ways to prevent and lessen the impact of road crashes. Over 100 experts, from all continents and different sectors -- including transport, engineering, health, police, education and civil society -- have worked to produce the report. Charts and tables.
Author: Alan M. Nahum Publisher: Springer Science & Business Media ISBN: 9780387988207 Category : Medical Languages : en Pages : 660
Book Description
This second edition, completely revised and expanded with a new chapter on lower extremity trauma, presents chapters written by widely recognized authorities in the field of human traumatic injury. The topics covered range from automobile restraint systems to cell and tissue biomechanics, and will interest a variety of scholars and professionals including physicians; biomechanical researchers; mechanical, biomedical and automotive engineers; as well as attorneys and jurists involved in accidental injury cases.
Author: Yong Peng
Author: Yong Peng
Author: Jianfeng Yao
Author: Kyle A. Ott
Author: Jianfeng Yao
Author: Timothy A. Hoyt
Author: Michael W. Monk
Author: National Research Council
Author: Marjorie Peden
Author: Francisco J. Lopez-Valdes
Author: Alan M. Nahum