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THUMS User Community Project Overview Th. Fuchs 1, K. Zhou 1, Prof. Dr. S. Peldschus 1,2 1 Biomechanics Group, Institute of Legal Medicine, University of Munich 2 Hochschule Furtwangen University Stuttgart, 12.11.2013 Informationstag für Biomechanik

OUTLINES 1. What is THUMS User Community? General Information 2. Background THUMS (Total HUman Model for Safety) 3. Motivation 4. Aims of the project 5. Process to Master Model 6. Activities 7. Status 8. Validation example - Neck under compression 9. Contact 2

General Information Coordinator: University of Munich (LMU Ludwig-Maximilians-Universität) Duration of project: 3 years (12/2012 11/2015) Financing: yearly contribution to project budget by the partners Project Partners: Adam Opel AG AUDI AG Autoliv BMW AG Daimler AG Porsche AG Toyota Motor Corporation Volkswagen Aktiengesellschaft Subcontractors: Associated Partners: DYNAmore, ESI, Simulia Bundesanstalt für Straßenwesen (BASt) Partnership for Dummy Technology and Biomechanics (PDB) Virtual Vehicle (ViF) 3

Project Partners Associated Partners Subcontractor 4

Background Numeric Human Body Models (HBMs) gain in importance in the field of passive safety Several advantages of HBMs towards Dummies High biofidelity Simulation of stress distribution within tissues Simulation of fractures Influence of muscle activity Evaluation of occupant kinematics and injury potential possible with HBMs LMU, Institute of Legal Medicine LMU, Institute of Legal Medicine 5

THUMS Total HUman Model for Safety FE Human Model THUMS version 3 ( JSOL Corporation) Developed by Toyota Motor Corporation and Toyota Central R&D Labs Human-like behaviour in crash Human-like kinematics Realistic loading representation in crash Representing American male body 50th percentile size (175cm, 77kg) Available in different versions JSOL Corporation Used within THUMS User Community THUMS version 4 ( JSOL Corporation) 6

Motivation Common motivation and interest of project partners to constantly improve vehicle and traffic safety Implementation of HBMs as tool for the evaluation of passive safety systems Harmonisation, provision and maintenance of THUMS in 3 different codes (DYNA, Pam, Abaqus) No uniform model available among project partners THUMS was further developed by several project partners Daimler: shoulder, improved mesh Autoliv: thorax No comparable results of crash simulations 7

Aims of the project Harmonisation, provision and maintenance of a FE Human Body Model for vehicle and traffic safety application Safeguarding effective and robust usability of THUMS by implementation of a dedicated tool management, support and documentation. Initiation of further research activities to improve biomechanical model quality and validity. Exchange and documentation of research results and / or agreed initiation of further research activities to push on with appropriate further development in terms of continuous validation of biomechanical model quality and application oriented improvement of an anatomic representation of the human. Set up a platform to share and exchange pre-competitive know-how and experience with the application of THUMS. Discuss and formulate framework requirements to establish a permanent institution by the end of this project to continue this platform approach. Gain new members contributing to the project 8

Process to TUC Master Model Validation Catalogue A THUMS 3 original Daimler 9 validation cases on neck, thorax, pelvis, shoulder and whole body Basic validation checks Robustness checks Basic tracking Cases defined for occupant and pedestrian model independently Autoliv TUC Element Criteria Check of the assembled Master Model by commonly defined element criteria Validation Catalogue B / C List of validation cases for biomechanical assessment Cases defined for occupant and pedestrian model independently 9

Process to TUC Master Model THUMS 3 original Validated 1st Master Model presumably available in LS-DYNA beginning of 2014 Daimler Autoliv Validated 1st Master Model presumably available in all 3 codes March/April 2014 10

Activities THUMS User Community 11

Status 1. Tool Management: Process to first Master New model (occupant) assembled Validations running finished beginning of next year Master model available in DYNA as occupant and pedestrian presumably beginning of next year Translation into Pam and Abaqus starting 2014 2. Biomechanics Project with University of Coventry anticipated (OOP with airbag) 3. Utility and Auxiliary Tools Development of a TUC positioning and scaling tool - started Development of TUC post-processing and biomechanical assessment tool - planned 4. Administration TUC website www.tuc-project.org TUC newsletter (please subscribe at the homepage!) 12

Validation of neck under compression Validation of neck under compression necessary for the evaluation of new pedestrian safety systems Windscreen airbags Active bonnet Volvo, AutoMotoTV Data from PMHS experiments Experimental setup Result corridors Simulation setup Boundary conditions of experiment Simulation of experiment comparison with result data of experiments Do data match? No Modification of model Bug fixing Contact definitions Boundary conditions Material model/parameter Mesh quality Anatomy Etc. No Yes Comparison of results Do data match? Yes Validated model 13

Validation of neck under compression Validation against experiments of W. Nightingale, H. McElhaney (Duke University, USA, 1995) PMHS compression tests Head-neck cut free under T1 Removal of muscular tissue, conservation of ligaments Different angles of impact plate (-15, 0, 15, 30 ) Impact velocity: 3.2 m/s Torso mass: 16kg Forces: Contact force between head and impact plate T1 force Nightingale et al., 1995 Nightingale et al., 1995 14

Validation of neck under compression 1. Experimental setup 2. Bug fixing Neck penetrating into jaw Initial penetration of ALL (Anterior Longitudinal Ligament) Intervertebral disc sliding 3. Model modification Modification of material models and parameters Mesh refinement (disc and ALL) Extra shell part Contact definitions 15

Validation of neck under compression Results 1. Head contact force 2. T1 force - Experiment/Nightingale - unmodified model - validated model - - Experiment/Nightingale Experiment/Nightingale - - unmodified unmodified model model - - validated validated model model Force [kn] Force [kn] Time [ms] Time [ms] Contact force between head and impact plate Successful validation: simulation results approximate experimental data (~80%) Force at T1 vertebra Peaks: Buckling modes Fractures / dislocations (e.g. basilar skull fracture) 16

Contact Project Management: Therese Fuchs tel. +49 89 2180 73365 therese.fuchs@med.uni-muenchen.de Scientific Coordination: Prof. Dr. Steffen Peldschus 17

Thank you for your attention. Any questions? www.tuc-project.org 18