A Strain Rate Dependent Computational Model of Ductile Damage for C(T) Specimen

H. S. Nam, J. Y. Jeon, J. S. Kim, J. W. Kim, Yun-Jae Kim

Research output: Chapter in Book/Report/Conference proceedingConference contribution

1 Citation (Scopus)

Abstract

This paper is based on a ductile failure simulation under dynamic loading conditions using finite element (FE) analyses. This paper proposed to implement fracture simulation based on the energy based numerical ductile fracture model. The energy based numerical ductile fracture model is determined to be incremental damage in terms of stress triaxiality (σme) and fracture strain energy (Wf) for dimple fracture from tensile test result with FE analyses technique. Since dynamic loading effect is especially important to assess crack-like defect components, this work propose the integrated model which combines quasi-static with dynamic loading effect. In order to validate energy based numerical ductile fracture model in dynamic loading conditions, this paper compares FE results with test results. The tensile properties for SA 508 Gr. 1a carbon steel were examined over a wide range of strain rates. Five different strain rate tensile test results are fitted by Johnson-Cook model. Also, two types of notch tensile tests were examined under four different strain rates. The energy based numerical ductile fracture model criterion was calibrated by FE analyses with strain rate dependent tensile and notch test results. The calibrated damage model predicts CT test result. Simulated results agree well with experimental data.

Original languageEnglish
Title of host publicationProcedia Engineering
PublisherElsevier Ltd
Pages861-867
Number of pages7
Volume130
DOIs
Publication statusPublished - 2015
Event14th International Conference on Pressure Vessel Technology, 2015 - Shanghai, China
Duration: 2015 Sep 232015 Sep 26

Other

Other14th International Conference on Pressure Vessel Technology, 2015
CountryChina
CityShanghai
Period15/9/2315/9/26

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Keywords

  • Ductile fracture
  • Fracture simulation
  • High strain condition

ASJC Scopus subject areas

  • Engineering(all)

Cite this

Nam, H. S., Jeon, J. Y., Kim, J. S., Kim, J. W., & Kim, Y-J. (2015). A Strain Rate Dependent Computational Model of Ductile Damage for C(T) Specimen. In Procedia Engineering (Vol. 130, pp. 861-867). Elsevier Ltd. https://doi.org/10.1016/j.proeng.2015.12.212