A Finite Element Model of the Foot and Ankle for Automotive Impact Applications

Shin, Jeongho; Yue, Neng; Untaroiu, Costin D.

doi:10.1007/s10439-012-0607-3

Cited by 98 publications

(62 citation statements)

References 32 publications

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“…The development of this HBM was based on a multimodality medical image and external anthropometry data set of a volunteer representing a 50th percentile male in terms of height (174.9 cm) and weight (78.6 ± 0.77 kg), described by Gayzik et al (Gayzik et al 2011;Gayzik et al 2012). The model has since undergone numerous validation simulations at both the regional (e.g., DeWit et al 2012;Li et al 2010;Shin et al 2012;Soni et al 2015) and full body levels (e.g., Hayes et al 2014;Toyota 2010;Yang et al 2006). Additional information on the development of the model can be found in the GHBMC M50 user's manual (GHBMC 2011).…”

Section: Introductionmentioning

confidence: 99%

Modular use of human body models of varying levels of complexity: Validation of head kinematics

Decker

Koya

Davis

et al. 2017

Traffic Injury Prevention

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Objective: The significant computational resources required to execute detailed human body finiteelement models has motivated the development of faster running, simplified models (e.g., GHBMC M50-OS). Previous studies have demonstrated the ability to modularly incorporate the validated GHBMC M50-O brain model into the simplified model (GHBMC M50-OS+B), which allows for localized analysis of the brain in a fraction of the computation time required for the detailed model. The objective of this study is to validate the head and neck kinematics of the GHBMC M50-O and M50-OS (detailed and simplified versions of the same model) against human volunteer test data in frontal and lateral loading. Furthermore, the effect of modular insertion of the detailed brain model into the M50-OS is quantified. Methods: Data from the Navy Biodynamics Laboratory (NBDL) human volunteer studies, including a 15g frontal, 8g frontal, and 7g lateral impact, were reconstructed and simulated using LS-DYNA. A five-point restraint system was used for all simulations, and initial positions of the models were matched with volunteer data using settling and positioning techniques. Both the frontal and lateral simulations were run with the M50-O, M50-OS, and M50-OS+B with active musculature for a total of nine runs. Conclusion:The greatest departure from the detailed occupant models were noted in lateral flexion, potentially indicating the need for further study. Precise modeling of the belt system however was limited by available data. A sensitivity study of these parameters in the frontal condition showed that belt slack and muscle activation have a modest effect on the ISO score. The reduction in computation time of the M50-OS+B reduces the burden of high computational requirements when handling detailed HBMs. Future work will focus on harmonizing the lateral head response of the models and studying localized injury criteria within the brain from the M50-O and M50-OS+B.

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Section: Introductionmentioning

confidence: 99%

Modular use of human body models of varying levels of complexity: Validation of head kinematics

Decker

Koya

Davis

et al. 2017

Traffic Injury Prevention

View full text Add to dashboard Cite

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“…Today, Computer-Aided Engineering (CAE) is known as a necessary technique which helps the engineers to remarkably save time and money in the design and manufacturing process. In the recent years, a wide range of studies have been carried out to develop Finite Element (FE) analyses as alternatives of the experimental conventional procedures of automotive design such as (Noise, Vibration and Harshness) NVH Sobieski et al (2001), safety Shin et al (2012) and strength Palmonella et al (2005).…”

Section: Introductionmentioning

confidence: 99%

Parametric Modal Study and Optimization of the Floor Pan of a B-Segment Automotive Using a Hybrid Method of Taguchi and a Newly Developed MCDM Model

Shojaeefard

Khalkhali

Lahijani

2016

Lat. Am. j. solids struct.

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“…A new cortical thickness mapping technique was applied to the coxal bone from CT images and the effects of posture on hip injury tolerance were analyzed (Kim et al 2012;Yue et al 2014). The lower limbs were also tested under complex loading resulting from blunt impacts Shin et al 2012;Untaroiu et al 2013). The fullbody M50-O was validated by mass distribution and in a variety of hub and lateral impacts Park et al 2013;Vavalle et al 2015;Vavalle et al 2012).…”

Section: Introductionmentioning

confidence: 99%

Development of a Computationally Efficient Full Human Body Finite Element Model

Schwartz

Guleyupoglu

Koya

et al. 2015

Traffic Injury Prevention

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Introduction:A simplified and computationally efficient human body finite element model is presented. The model complements the Global Human Body Models Consortium (GHBMC) detailed 50th percentile occupant (M50-O) by providing kinematic and kinetic data with a significantly reduced run time using the same body habitus.Methods: The simplified occupant model (M50-OS) was developed using the same source geometry as the M50-O. Though some meshed components were preserved, the total element count was reduced by remeshing, homogenizing, or in some cases omitting structures that are explicitly contained in the M50-O. Bones are included as rigid bodies, with the exception of the ribs, which are deformable but were remeshed to a coarser element density than the M50-O. Material models for all deformable components were drawn from the biomechanics literature. Kinematic joints were implemented at major articulations (shoulder, elbow, wrist, hip, knee, and ankle) with moment vs. angle relationships from the literature included for the knee and ankle. The brain of the detailed model was inserted within the skull of the simplified model, and kinematics and strain patterns are compared.Results: The M50-OS model has 11 contacts and 354,000 elements; in contrast, the M50-O model has 447 contacts and 2.2 million elements. The model can be repositioned without requiring simulation. Thirteen validation and robustness simulations were completed. This included denuded rib compression at 7 discrete sites, 5 rigid body impacts, and one sled simulation. Denuded tests showed a good match to the experimental data of force vs. deflection slopes. The frontal rigid chest impact simulation produced a peak force and deflection within the corridor of 4.63 kN and 31.2%, respectively. Similar results vs. experimental data (peak forces of 5.19 and 8.71 kN) were found for an abdominal bar impact and lateral sled test, respectively. A lateral plate impact at 12 m/s exhibited a peak of roughly 20 kN (due to stiff foam used around the shoulder) but a more biofidelic response immediately afterward, plateauing at 9 kN at 12 ms. Results from a frontal sled simulation showed that reaction forces and kinematic trends matched experimental results well. The robustness test demonstrated that peak femur loads were nearly identical to the M50-O model. Use of the detailed model brain within the simplified model demonstrated a paradigm for using the M50-OS to leverage aspects of the M50-O. Strain patterns for the 2 models showed consistent patterns but greater strains in the detailed model, with deviations thought to be the result of slightly different kinematics between models. The M50-OS with the deformable skull and brain exhibited a run time 4.75 faster than the M50-O on the same hardware.Conclusions: The simplified GHBMC model is intended to complement rather than replace the detailed M50-O model. It exhibited, on average, a 35-fold reduction in run time for a set of rigid impacts. The model can be used in a modular fashion with the M50-O and more broadly can...

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A Finite Element Model of the Foot and Ankle for Automotive Impact Applications

Cited by 98 publications

References 32 publications

Modular use of human body models of varying levels of complexity: Validation of head kinematics

Modular use of human body models of varying levels of complexity: Validation of head kinematics

Parametric Modal Study and Optimization of the Floor Pan of a B-Segment Automotive Using a Hybrid Method of Taguchi and a Newly Developed MCDM Model

Development of a Computationally Efficient Full Human Body Finite Element Model

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