Determining Strain Rate Dependence of Human Body Soft Tissues Using a Split Hopkinson Pressure Bar
Crash simulations with Finite Element human body models would be better predictors of injury than with dummy models. During dynamic loading, human body soft tissues are exposed to varying strain rates. To characterize them, the conventional Split Hopkinson Pressure Bar (SHPB) is modified in order to test soft tissues. Experimentally determined engineering stress vs engineering strain curves for erector spinae, hamstring and gluteus max muscles are reported in the strain rate range of from 250/s to 1000/s. The loading curves exhibit multi linear behavior with increasing strain rate shifting the transition points between the slopes. For the covering abstract see ITRD E141569.
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Authors:
- CHAWLA, A
- MUKHERJEE, S
- Marthe, R
- KARTHIKEYAN, B
- Publication Date: 2006
Language
- English
Media Info
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Serial:
- 2006 INTERNATIONAL IRCOBI CONFERENCE ON THE BIOMECHANICS OF IMPACT
- Publisher: IRCOBI (International Research Council on the Biomechanics of Impacts) Secretariat-INRETS
Subject/Index Terms
- TRT Terms: Anthropometry; Biophysics; Conferences; Crashes; Deformation; Finite element method; Muscles; Pressure; Simulation
- ITRD Terms: 2060: Biomechanics; 1631: Collision; 8525: Conference; 5595: Deformation; 6490: Finite element method; 2055: Human body; 2032: Muscle; 5412: Pressure; 9103: Simulation
- Subject Areas: Data and Information Technology; Safety and Human Factors; I84: Personal Injuries;
Filing Info
- Accession Number: 01131696
- Record Type: Publication
- Source Agency: TRL
- Files: ITRD
- Created Date: Jul 2 2009 7:29AM