Theoretical model for predicting uniaxial stress-strain relation by dual conical indentation based on equivalent energy principle

For conical indentation, the strain energy is a function of the semi-vertical cone angle, the indentation depth and the stress-strain relation. According to equivalent energy principle of representative volume elements (RVE) and the classical cavity assumption for material deformation region, the fu...

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Published inActa materialia Vol. 121; pp. 181 - 189
Main Authors Chen, Hui, Cai, Li-xun
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.12.2016
Subjects
Conical indentation
Deformation
Equivalence
Equivalent energy principle
Finite element analysis
Finite element method
Holes
Indentation
Mathematical analysis
Mathematical models
Mechanical properties
Stress-strain relationships
Mechanical properties
Conical indentation
Finite element analysis
Equivalent energy principle
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Abstract For conical indentation, the strain energy is a function of the semi-vertical cone angle, the indentation depth and the stress-strain relation. According to equivalent energy principle of representative volume elements (RVE) and the classical cavity assumption for material deformation region, the function with dual-parameters about volume and deformation is theoretically derived in the present study. This original equivalent-energy indentation model (EIM) is capable of forward-predicting load-depth relation and reverse-predicting uniaxial stress-strain relation for ductile materials only based on loading part of indentation. Further analyses show that the forward and reverse predicted results from EIM method are in excellent agreement with those by finite element analyses (FEA). Macro conical indentation experiments on five types of metals have been conducted using conventional indenters which are similar to Rockwell sclerometer. Consequently, the stress-strain relations predicted by EIM are quite close to those from standard tensile tests. [Display omitted]
AbstractList For conical indentation, the strain energy is a function of the semi-vertical cone angle, the indentation depth and the stress-strain relation. According to equivalent energy principle of representative volume elements (RVE) and the classical cavity assumption for material deformation region, the function with dual-parameters about volume and deformation is theoretically derived in the present study. This original equivalent-energy indentation model (EIM) is capable of forward-predicting load-depth relation and reverse-predicting uniaxial stress-strain relation for ductile materials only based on loading part of indentation. Further analyses show that the forward and reverse predicted results from EIM method are in excellent agreement with those by finite element analyses (FEA). Macro conical indentation experiments on five types of metals have been conducted using conventional indenters which are similar to Rockwell sclerometer. Consequently, the stress-strain relations predicted by EIM are quite close to those from standard tensile tests.
For conical indentation, the strain energy is a function of the semi-vertical cone angle, the indentation depth and the stress-strain relation. According to equivalent energy principle of representative volume elements (RVE) and the classical cavity assumption for material deformation region, the function with dual-parameters about volume and deformation is theoretically derived in the present study. This original equivalent-energy indentation model (EIM) is capable of forward-predicting load-depth relation and reverse-predicting uniaxial stress-strain relation for ductile materials only based on loading part of indentation. Further analyses show that the forward and reverse predicted results from EIM method are in excellent agreement with those by finite element analyses (FEA). Macro conical indentation experiments on five types of metals have been conducted using conventional indenters which are similar to Rockwell sclerometer. Consequently, the stress-strain relations predicted by EIM are quite close to those from standard tensile tests. [Display omitted]
Author Cai, Li-xun
Chen, Hui
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  givenname: Li-xun
  surname: Cai
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Snippet For conical indentation, the strain energy is a function of the semi-vertical cone angle, the indentation depth and the stress-strain relation. According to...
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SubjectTerms Conical indentation
Deformation
Equivalence
Equivalent energy principle
Finite element analysis
Finite element method
Holes
Indentation
Mathematical analysis
Mathematical models
Mechanical properties
Stress-strain relationships
Title Theoretical model for predicting uniaxial stress-strain relation by dual conical indentation based on equivalent energy principle
URI https://dx.doi.org/10.1016/j.actamat.2016.09.008
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