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Analysis of Hyperelastic Materials

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Title: Analysis of Hyperelastic Materials


1
Analysis of Hyperelastic Materials
  • MEEN 5330
  • Fall 2006
  • Added by the professor

2
Introduction
  • Rubber-like materials ,which are characterized by
    a relatively low elastic modulus and high bulk
    modulus are used in a wide variety of structural
    applications.
  • These materials are commonly subjected to large
    strains and deformations.
  • Hyperelastic materials experience large strains
    and deformations .
  • A material is said to be hyperelastic if there
    exists an elastic potential W(or strain energy
    density function) that is a scalar function of
    one of the strain or deformation tensors, whose
    derivative with respect to a strain component
    determines the corresponding stress component .

3
Introduction Contd..
  • Second Piola-Kirchoff Stress Tensor
  • Lagrangian Strain Function
  • Component of Cauchy-Green Deformation Tensor

4
Introduction Contd..
  • Eigen values of are and exist
    only if
  • are the invariants of cauchy-deformation tensor.

5
  • MATERIAL MODELS
  • Why material models?
  • Material models predict large-scale material
    deflection and deformations.
  • Different material models
  • Basically 2 types
  • Incompressible
  • Mooney-Rivlin
  • Arruda-Boyce
  • Ogden
  • Compressible
  • Blatz-Ko
  • Hyperfoam

6
  • Incompressible
  • Mooney-Rivlin works with incompressible
    elastomers with strain upto 200. For example,
    rubber for an automobile tyre.
  • Arruda-Boyce is well suited for rubbers such as
    silicon and neoprene with strain upto 300 . this
    model provides good curve fitting even when test
    data are limited.
  • Ogden works for any incompressible material with
    strain up to 700. This model give better curve
    fitting when data from multiple tests are
    available.

7
  • Compressible
  • Blatz-Ko works specifically for compressible
    polyurethane foam rubbers.
  • Hyperfoam can simulate any highly compressible
    material such as a cushion, sponge or padding

8
Mooney-Rivlin material
  • In 1951,Rivlin and Sunders developed a a
    hyperelastic material model for large
    deformations of rubber.
  • This material model is assumed to be
    incompressible and initially isotropic.
  • The form of strain energy potential for a
    Mooney-Rivlin material is given as W
  • Where
  • , and are material
    constants.

9
  • Determining the Mooney-Rivlin material
    constants
  • The hyperelastic constants in the strain energy
    density function of a material its mechanical
    response .
  • So, it is necessary to assess the Mooney-Rivlin
    constants of the materials to obtain successful
    results of a hyperelastic materials.
  • It is always recommended to take the data from
    several modes of deformation over a wide range of
    strain values.
  • For hyperelastic materials, simple deformation
    tests (consisting of six deformation models ) can
    be used to determine the Mooney-Rivlin
    hyperelastic material.

10
Six deformation models

11
Six deformation modes contdEven though the
superposition of tensile or compressive
hydrostatic stresses on a loaded incompressible
body results in different stresses, it does not
alter deformation of a material.Upon the
addition of hydrostatic stresses ,the following
modes of deformation are found to be
identical.1.Uniaxial tension and Equibiaxial
compression,2.Uniaxial compression and Equiaxial
tension, and3.Planar tension and Planar
Compression.It reduces to 3 independent
deformation states for which we can obtain
experimental data.

12
3 independent deformation statesIn the next
section , we will brief the relationships for
each independent testing mode.
13
Deformation Testing Modes
  • Equibiaxial Compression
  • Equibiaxial Tension
  • Pure Shear Deformation

14
Deformation Testing Modes Contd..
  • Equibiaxial Compression
  • Stretch in direction being loaded
  • Stretch in directions not being loaded
  • Due to incompressibility,

15
Deformation Testing Modes Contd..
  • For uniaxial tension, first and second invariants
  • Stresses in 1 and 2 directions

16
Deformation Testing Modes Contd..
  • Principal true stress,

17
Deformation Testing Modes Contd..
  • Equibiaxial Tension Equivalently, Uniaxial
    Compression)
  • Stretch in direction being loaded
  • Stretch in direction not being loaded
  • Utilizing incomressibility equation,

18
Deformation Testing Modes Contd..
  • For equilibrium tension,
  • Stresses in 1 and 3 directions,

19
Deformation Testing Modes Contd..
  • Principal true stress for Equibiaxial Tension,

20
Deformation Testing Modes Contd..
  • Pure Shear Deformation
  • Due to incompressibility,
  • First and Second strain invariants

21
Deformation Testing Modes Contd..
  • Stresses in 1 and 3 directions
  • Principal pure shear true stress

22
Stress Error Correction
  • To minimize the error in Stresses, we perform a
    least-square fit analysis. Mooney-Rivlin
    constants can be determined from stress-strain
    data.
  • Least Square fit minimizes the sum of squared
    error between the experimental values(if any)
    values and cauchy predicted stress values.
  • E Relative error.
  • Experimental Stress Values.
  • Cauchy stress values.
  • No. of Experimental Data points.
  • This yields a set of simultaneous equations which
    are solved for Mooney-Rivlin Materials Constants.

23
Problem statement
  • How do we determine the principal true stresses
    in Equibiaxial compression or Equibiaxial
    tension test? Show the figure to illustrate the
    deformation modes.

24
References
  • 1.Brian Moran,Wing Kam Liu,Ted Belytschko,Hyper
    elastic material,Non-Linear Finite elements for
    continua and Structures,September 2001,(264-265).
  • 2.Ernest D.George,JR .,George A.HADUCH and
    Stephen JORDAN The integration of analysis and
    testing for the the simulation of the response
    of hyper elastic materials ,1998 Elsevier science
    publishers B.V(North Holland).
  • William Prager,Introduction to mechanics of
    Continua,Dover Publications,New
    York,1961,(157,185,209).
  • Theory reference,Chapter 4.Structures with
    Material Non-linearities,Hyper elasticity ANSYS
    6.1 Documentation .Copyright1971,1978,1982,1985,19
    87,1992-2002,SAS IP.
  • Web referencewww.impactgensol.com

25
Conclusions
  • In this, we have analysed Mooney-Rivlin Materials
    constants. Mooney-Rivlin Material C10,C01 by
    using 6 deformation modes.
  • We determine principle stresses using Equibiaxial
    compression(Uniaxial Tension), Equibiaxial
    Tension(Uniaxial Compression), Pure shear.
  • Resultant values are taken as Cumulative values
    and the errors in the resultant values are
    minimised using Least-square fit Analysis.
  • According to this analysis, we can say that
    materials having high stress-strain values,
    mooney-rivlin model can be used to determine the
    material constants for hyperelastic materials.
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