Safety Counter Measures: A Comprehensive Crashworthiness Study of Out-Of-Position (OOP) Airbag Deployment and Passenger Impact

Potula, Suryatej Reddy

12 May 2012

The objective of this research is to simulate crashworthiness for Out-of-Position (OOP) occupants incorporating a 50th percentile Hybrid III dummy and a side curtain airbag in a 1996 Dodge Neon under side impact scenarios. Two different methods of airbag techniques namely, the uniform pressure (UP) and the smooth particle hydrodynamics (SPH) were compared. This study revealed that there is minimal difference between UP and SPH methods when the dummy’s head impacts the airbag after it has fully inflated. However, when the dummy’s head impacts the airbag during the inflation process, the modeling of the airbag gas dynamics becomes critical in predicting the dummy response. The SPH method, which models the gas dynamics in the airbag, causes the airbag to unroll more uniformly. Depending on the timing of the dummy’s head impact with the airbag these differences in inflation can produce significant differences in dummy head accelerations.

finite element analysis

out-of-position

Crashworthiness

Occupant safety

Investigation of W-Beam Energy-Absorbing Guardrail End Terminal Safety Performance Using Finite Element Modeling

Meng, Yunzhu

23 August 2022

Guardrails were designed to deter vehicle access to off-road areas and consequently prevent hitting rigid fixed object alongside the road (e.g., trees, utility poles, traffic barriers, etc.). However, guardrails cause 10% of deaths of vehicle-to-fixed object crashes which has attracted attention in the highway safety community on the vehicle-based injury criteria used in guardrail regulations. The objectives of this study were 1) to develop and validate a Finite Element (FE) model of the ET-Plus, a commonly used energy-absorbing guardrail end terminal; 2) to examine the conditions of in-service end terminals, and to evaluate the performance of the damaged relative to undamaged end terminals in simulated impacts; 3) to investigate both full-body and body region driver injury probabilities during car-to-end terminal crashes using dummy and human body FE models; to analyze the relationship between the vehicle-based crash severity metrics used currently in regulations and the injury probabilities assessed using biomechanics injury criteria; and 4) to quantify the influence of pre-impact conditions on injury probabilities. In this dissertation, an ET-Plus FE model was developed based on publicly available data on ET-Plus dimensions and material properties. The model was validated against the NCHRP-350 crash tests. The developed ET-Plus model was used to develop to five damaged ET-Plus whose damage patterns were identified based on an investigation of in-service end terminals mounted along U.S. roads. It was observed that damaged end terminals usually increase collision severity compared to undamaged end terminals. Meanwhile, a total of 40 FE impact simulations between a car with a dummy/human body model in the driver seat and an end terminal model were performed in various configurations. The vehicle-based severity metrics were observed to be correlated to full-body and certain body-region injury risks while no head injury risk could be predicted. The results pointed out that more advanced vehicle-based metrics should be proposed and investigated to improve the predictability in terms of occupant injury risks in the crash tests. The simulation models could also supplement crash compliance tests of new hardware designs, by investigating their safety performance for a large variety of pre-impact conditions, observed in traffic accidents, but not included the compliance tests. / Doctor of Philosophy / Guardrails were designed to deter vehicle access to off-road areas and consequently prevent hitting rigid fixed object alongside the road (e.g., trees, utility poles, traffic barriers, etc.). However, guardrails cause 10% of deaths of vehicle-to-fixed object crashes which has attracted attention in the highway safety community on the vehicle-based injury criteria used in guardrail regulations. The objectives of this study were 1) to develop and validate a Finite Element (FE) model of the ET-Plus, a commonly used energy-absorbing guardrail end terminal; 2) to examine the conditions of in-service end terminals, and to evaluate the performance of the damaged relative to undamaged end terminals in simulated impacts; 3) to investigate both full-body and body region driver injury probabilities during car-to-end terminal crashes using dummy and human body FE models; to analyze the relationship between the vehicle-based crash severity metrics used currently in regulations and the injury probabilities assessed using biomechanics injury criteria; and 4) to quantify the influence of pre-impact conditions on injury probabilities. In this dissertation, an ET-Plus FE model was developed based on publicly available data on ET-Plus dimensions and material properties. The model was validated against the NCHRP-350 crash tests. The developed ET-Plus model was used to develop to five damaged ET-Plus whose damage patterns were identified based on an investigation of in-service end terminals mounted along U.S. roads. It was observed that damaged end terminals usually increase collision severity compared to undamaged end terminals. Meanwhile, a total of 40 FE impact simulations between a car with a dummy/human body model in the driver seat and an end terminal model were performed in various configurations. The vehicle-based severity metrics were observed to be correlated to full-body and certain body-region injury risks while no head injury risk could be predicted. The results pointed out that more advanced vehicle-based metrics should be proposed and investigated to improve the predictability in terms of occupant injury risks in the crash tests. The simulation models could also supplement crash compliance tests of new hardware designs, by investigating their safety performance for a large variety of pre-impact conditions, observed in traffic accidents, but not included the compliance tests.

Roadside safety

Occupant safety

Computational biomechanics

Finite Element

Investigation on seat structural integrity and occupant safety in coach rollover

Giahi, Hamid

30 January 2017

Motor coaches are an integral part of the transportation system. It was observed that occupant fatalities and serious injuries occur in rollover more frequently than in any other type of accidents for these vehicles. Several regulations such as Economic Commission for Europe Regulation 66 (ECE R66) are issued to minimize the catastrophic consequences of rollover accidents. Passing “Motorcoach safety plan” which is based on a complete vehicle rollover test of ECE R66 will be mandatory in North America in the near future. However, the cost of a single physical test encourages researchers to perform numerical simulations prior to a complete vehicle rollover test. In this thesis, the integrity of a coach seat and the effects of different restraint configurations on the safety of passengers in rollover are numerically studied. To perform this research, a new modeling approach, which is computationally effective and highly suitable for parametric studies, is proposed. Firstly, a detailed model of two seats of a coach is developed and validated against experimental results. Anthropomorphic Test Devices are then introduced to the model and acceleration history of a physical rollover test is imposed on the system. The model is solved using non-linear explicit dynamic Finite Element code LS-DYNA®. Injury criteria values are extracted and compared to the experimental results. An acceptable level of correlation is achieved that confirms the validity of the model and the reliability of the modeling approach. The integrity of the seat in a rollover is analyzed showing the necessity of an anchorage test prior to a whole coach rollover test. The results of a parametric study on the safety of passengers reveal the high probability of partial ejection if the retractor does not lock properly in a rollover. It is also shown that the safety of occupants can be improved if retractor pretensioners be introduced to coaches. / February 2017

Parents' Knowledge of Child-Passenger Safety and Child-Passenger Restraint Usage

Cadore, Amanda

01 January 2019

Although occupant protection laws exist, limited research has been conducted on how current child passenger safety (CPS) issues and CPS marketing strategies relate to child passenger safety seat (CPSS) usage. The purpose of this cross-sectional study was to analyze the relationship between parents' perception and knowledge of CPS issues and CPSS usage rates. The diffusion of innovation and the social marketing theories provided the frameworks for this study. The overall research question for the study examined the correlation between parents' knowledge of CPS issues and CPSS usage. Data (participants' surveys, car seat check-up information, and observational statistics) were collected from events that occurred in 3 locations across the county. The population consisted of a convenience sample of adults (parents of children 8-years-old and younger) from each of the locations. The study survey was distributed to 93 participants and only 71 surveys (76.34%) were received for analysis. Data analysis methods included deductive coding, Cronbach's alpha, descriptive statistics, hypotheses testing, linear regression, and Pearson Correlation. The overall test results showed that there were no significant relationships between the independent variable predictors (parents' knowledge of proper CPSS installation techniques, CPS laws and regulations, and marketing strategies) and the dependent variable (CPSS usage rates). The overall study was not statistically significant. The study should be replicated, however modified (on a larger scale for a longer period). Thus, having a stronger possibility to impact the community (producing noteworthy results and promoting social change).

Child Passenger Safety

Injury Prevention

Occupant Safety

Public Health Education and Promotion

Advanced Simulation Methodologies For Crashworthiness And Occupant Safety Assessment Of An Indian Railways Passenger Coach

Prabhune, Prajakta Vinayak

07 1900

Accidents involving passenger trains happen regularly in India. The reasons for such accidents could be many; such as weather and flooding, faulty tracks, bridge collapse, collisions caused by signaling errors, mechanical failures, driver error, sabotage etc. The annual accident-related deaths as a percentage of the total number of passengers carried by Indian Railway may seem to be negligible, but the aim should be to achieve zero fatality as every single person killed is an irreplaceable loss to his/her family. It needs to be mentioned that in addition to fatalities for which exact numbers are not available, serious injuries and permanent disabilities caused by train accidents in India at present stand completely unaccounted for. In the absence of a large scale renovation and crash avoidance measures coupled with the propensity to increase the number of trains every year, enhancing passive safety is crucial i.e. crashworthiness and occupant safety of passenger coaches of Indian trains. In the current work, crashworthiness and occupant safety of the existing typical three-tier cabin passenger coach of Indian Railway in an event of collision accident are assessed with the aid of a finite element analysis. In the light of the published work on research in railroad equipment crashworthiness, the current work is intended to envisage the methodology to assess the Indian Railway passenger coach from the point of view of the crashworthiness and occupant safety using CAE (Computer aided engineering) based approach. It is involved with an extensive study of the structural crush behavior of an individual passenger coach car and its effect on the interaction between occupants and the coach interior. Here the structural crush behavior of a typical three-tier cabin passenger coach is evaluated for the head-on impact against a fixed and rigid barrier. The occupant response for the same scenario is also studied which can be viewed as a component of the actual occupant response due to the structural crush behavior of the passenger coach. This can give useful estimates of injury severity and fatalities that may occur in actual accidents. An FE model of the passenger coach structure was built and validated using International Railway Union (UIC) specified code OR 567-design requirements in terms of static loads constituting structural proof cases. These proof cases specify the static load values the coach body structure should withstand without any permanent deformation or failure when applied at the specified locations on the structural ends across the longitudinal axis. In addition, a favorable correlation between the simulation and actual experiment for drop impact behavior of the open section specimens, namely C-section and I-section, was obtained to validate the simulation methodology. LS-DYNA a nonlinear dynamic explicit FE solver was used to carry out all the dynamic impact simulations involved in the current work. The material modeling takes into account the strain rate effect which is essential for the material impact behavior study. The contact modeling was done using penalty contact method. The degrading effect of the buffer on the structural crush patterns which induced the undesirable global bending and jackknifing of the whole coach structure was demonstrated with the help of dynamic impact simulations of the coach structure. The quantification of occupant injury was done by occupant safety simulations using the Hybrid III 50th percentile male dummy FE model. The dummy having been designed for simulating automobile accident scenarios, its contacts had to be adapted to suit the excessive mobility conditions in the coach interior. The dummy was revalidated successfully for the head drop test, pendulum chest impact test, neck flexion and extension test and knee impact test. Impact simulations for three different speeds were performed by positioning the dummy close to the impact point. Injury criteria such as Head Injury Criterion, Chest Deceleration, Knee force level and Neck extension-flexion moments were used to estimate the injury severity level and fatality rate.

Rail Road Transport Safety - India

Indian Railways - Safety Assessment

Railroad Engineering