Soft Surface Roll Mechanics Parameters for Light Vehicle Rollover Accident Reconstruction

Light vehicle rollover accidents on soft surfaces can be modeled assuming constant drag with linear motion equations and other engineering principles. The concept of using segment average results to evaluate roll mechanics parameters throughout a roll sequence, and specifically, segment duration to...

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Main Author: Henry, Kevin Claude
Format: Others
Published: BYU ScholarsArchive 2007
Subjects:
Online Access:https://scholarsarchive.byu.edu/etd/1436
https://scholarsarchive.byu.edu/cgi/viewcontent.cgi?article=2435&context=etd
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spelling ndltd-BGMYU2-oai-scholarsarchive.byu.edu-etd-24352021-09-01T05:01:21Z Soft Surface Roll Mechanics Parameters for Light Vehicle Rollover Accident Reconstruction Henry, Kevin Claude Light vehicle rollover accidents on soft surfaces can be modeled assuming constant drag with linear motion equations and other engineering principles. The concept of using segment average results to evaluate roll mechanics parameters throughout a roll sequence, and specifically, segment duration to evaluate vehicle trajectory between ground impacts is developed. The trajectory model is presented, explained and compared to values obtained by analyzing digital video of rollover crash tests. Detailed film analysis procedures are developed to obtain data from rollover crash tests that are not otherwise documented. Elevation of the center of gravity of vehicles is obtained where instrumentation does not explicitly yield this data. Instantaneous center of gravity elevation data throughout a roll sequence provides the opportunity to calculate descend distances as a vehicle travels from one ground contact to another. This data is used to quantify severity of ground impacts as a vehicle interact with the ground throughout a roll sequence. Segment average analysis is a reasonable method for determining general roll mechanics parameters. Because of the chaotic nature of rollover accidents, the range of effective drag factors for a given roll surface may be quite large. Choosing an average of typical drag factors is a reasonable approach for a first-order approximation although certain parameters may be predicted less accurately than if actual values were known. The trajectory results demonstrate the influence of drag factor descent height calculations. Typical constant drag factors tend to overestimate descent height early in a roll sequence and underestimate descent height later in the sequence. The trajectory model is a useful tool to aid in understanding rollover mechanics although a rolling vehicle may be in contact with the ground for a significant fraction of a roll segment. The model should not be used at locations in roll sequences where there are extremes in translational center of gravity decelerations. These extremes include the segments immediately following overturn where there are large angular accelerations and large differences between the tangential velocity of the vehicle perimeter and the translational velocity of the center of gravity, as well as segments that include vehicle impacts with irregular topography. 2007-07-18T07:00:00Z text application/pdf https://scholarsarchive.byu.edu/etd/1436 https://scholarsarchive.byu.edu/cgi/viewcontent.cgi?article=2435&context=etd http://lib.byu.edu/about/copyright/ Theses and Dissertations BYU ScholarsArchive rollover accident reconstruction trajectory mechanics soft surface parameters roll drag factor angular velocity velocity energy moment of inertia center of rotation fmvss 208 dolly rollover test roll rate video film analysis Civil and Environmental Engineering
collection NDLTD
format Others
sources NDLTD
topic rollover
accident reconstruction
trajectory mechanics
soft surface
parameters
roll
drag factor
angular velocity
velocity
energy
moment of inertia
center of rotation
fmvss 208
dolly rollover test
roll rate
video
film analysis
Civil and Environmental Engineering
spellingShingle rollover
accident reconstruction
trajectory mechanics
soft surface
parameters
roll
drag factor
angular velocity
velocity
energy
moment of inertia
center of rotation
fmvss 208
dolly rollover test
roll rate
video
film analysis
Civil and Environmental Engineering
Henry, Kevin Claude
Soft Surface Roll Mechanics Parameters for Light Vehicle Rollover Accident Reconstruction
description Light vehicle rollover accidents on soft surfaces can be modeled assuming constant drag with linear motion equations and other engineering principles. The concept of using segment average results to evaluate roll mechanics parameters throughout a roll sequence, and specifically, segment duration to evaluate vehicle trajectory between ground impacts is developed. The trajectory model is presented, explained and compared to values obtained by analyzing digital video of rollover crash tests. Detailed film analysis procedures are developed to obtain data from rollover crash tests that are not otherwise documented. Elevation of the center of gravity of vehicles is obtained where instrumentation does not explicitly yield this data. Instantaneous center of gravity elevation data throughout a roll sequence provides the opportunity to calculate descend distances as a vehicle travels from one ground contact to another. This data is used to quantify severity of ground impacts as a vehicle interact with the ground throughout a roll sequence. Segment average analysis is a reasonable method for determining general roll mechanics parameters. Because of the chaotic nature of rollover accidents, the range of effective drag factors for a given roll surface may be quite large. Choosing an average of typical drag factors is a reasonable approach for a first-order approximation although certain parameters may be predicted less accurately than if actual values were known. The trajectory results demonstrate the influence of drag factor descent height calculations. Typical constant drag factors tend to overestimate descent height early in a roll sequence and underestimate descent height later in the sequence. The trajectory model is a useful tool to aid in understanding rollover mechanics although a rolling vehicle may be in contact with the ground for a significant fraction of a roll segment. The model should not be used at locations in roll sequences where there are extremes in translational center of gravity decelerations. These extremes include the segments immediately following overturn where there are large angular accelerations and large differences between the tangential velocity of the vehicle perimeter and the translational velocity of the center of gravity, as well as segments that include vehicle impacts with irregular topography.
author Henry, Kevin Claude
author_facet Henry, Kevin Claude
author_sort Henry, Kevin Claude
title Soft Surface Roll Mechanics Parameters for Light Vehicle Rollover Accident Reconstruction
title_short Soft Surface Roll Mechanics Parameters for Light Vehicle Rollover Accident Reconstruction
title_full Soft Surface Roll Mechanics Parameters for Light Vehicle Rollover Accident Reconstruction
title_fullStr Soft Surface Roll Mechanics Parameters for Light Vehicle Rollover Accident Reconstruction
title_full_unstemmed Soft Surface Roll Mechanics Parameters for Light Vehicle Rollover Accident Reconstruction
title_sort soft surface roll mechanics parameters for light vehicle rollover accident reconstruction
publisher BYU ScholarsArchive
publishDate 2007
url https://scholarsarchive.byu.edu/etd/1436
https://scholarsarchive.byu.edu/cgi/viewcontent.cgi?article=2435&context=etd
work_keys_str_mv AT henrykevinclaude softsurfacerollmechanicsparametersforlightvehiclerolloveraccidentreconstruction
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