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< | {{Continuum mechanics|cTopic=[[Solid mechanics]]}} | ||
In [[continuum mechanics]], an '''Arruda–Boyce model'''<ref name=AB>Arruda, E. M. and Boyce, M. C., 1993, '''A three-dimensional model for the large stretch behavior of rubber elastic materials,''', J. Mech. Phys. Solids, 41(2), pp. 389–412.</ref> is a [[hyperelastic material|hyperelastic]] [[constitutive model]] used to describe the mechanical behavior of [[rubber]] and other [[polymer]]ic substances. This model is based on the [[statistical mechanics]] of a material with a cubic [[representative volume element]] containing eight chains along the diagonal directions. The material is assumed to be [[incompressible]]. | |||
The [[strain energy density function]] for the '''incompressible''' Arruda–Boyce model is given by<ref name=Berg>Bergstrom, J. S. and Boyce, M. C., 2001, '''Deformation of Elastomeric Networks: Relation between Molecular Level Deformation and Classical Statistical Mechanics Models of Rubber Elasticity''', Macromolecules, 34 (3), pp 614–626, {{doi|10.1021/ma0007942}}.</ref> | |||
:<math> | |||
W = Nk_B\theta\sqrt{n}\left[\beta\lambda_{\mathrm{chain}} - \sqrt{n}\ln\left(\cfrac{\sinh\beta}{\beta}\right)\right] | |||
</math> | |||
where <math>N</math> is the number of chain segments, <math>k_B</math> is the [[Boltzmann constant]], <math>\theta</math> is the temperature in Kelvin, <math>n</math> is the number of chains in the network of a cross-linked polymer, | |||
:<math> | |||
\lambda_{\mathrm{chain}} = \sqrt{\tfrac{I_1}{3}} ~;~~ \beta = \mathcal{L}^{-1}\left(\cfrac{\lambda_{\mathrm{chain}}}{\sqrt{n}}\right) | |||
</math> | |||
where <math>I_1</math> is the first invariant of the left Cauchy–Green deformation tensor, and <math>\mathcal{L}^{-1}(x)</math> is the inverse [[Langevin function]] which can approximated by | |||
:<math> | |||
\mathcal{L}^{-1}(x) = \begin{cases} | |||
1.31\tan(1.59 x) + 0.91 x & \quad\mathrm{for}~|x| < 0.841 \\ | |||
\tfrac{1}{\sgn(x)-x} & \quad\mathrm{for}~ 0.841 \le |x| < 1 | |||
\end{cases} | |||
</math> | |||
For small deformations the Arruda–Boyce model reduces to the Gaussian network based [[neo-Hookean solid]] model. It can be shown<ref name=Horgan>Horgan, C.O. and Saccomandi, G., 2002, '''A molecular-statistical basis for the Gent constitutive model of rubber elasticity''', Journal of Elasticity, 68(1), pp. 167–176.</ref> that the [[Gent (hyperelastic model)|Gent model]] is a simple and accurate approximation of the Arruda–Boyce model. | |||
==Alternative expressions for the Arruda–Boyce model== | |||
An alternative form of the Arruda–Boyce model, using the first five terms of the inverse Langevin function, is<ref>Hiermaier, S. J., 2008, '''Structures under Crash and Impact''', Springer.</ref> | |||
:<math> | |||
W = C_1\left[\tfrac{1}{2}(I_1-3) + \tfrac{1}{20N}(I_1^2 -9) + \tfrac{11}{1050N^2}(I_1^3-27) + \tfrac{19}{7000N^3}(I_1^4-81) + \tfrac{519}{673750N^4}(I_1^5-243)\right] | |||
</math> | |||
where <math>C_1</math> is a material constant. The quantity <math>N</math> can also be interpreted as a measure of the limiting network stretch. | |||
If <math>\lambda_m</math> is the stretch at which the polymer chain network becomes locked, we can express the Arruda–Boyce strain energy density as | |||
:<math> | |||
W = C_1\left[\tfrac{1}{2}(I_1-3) + \tfrac{1}{20\lambda_m^2}(I_1^2 -9) + \tfrac{11}{1050\lambda_m^4}(I_1^3-27) + \tfrac{19}{7000\lambda_m^6}(I_1^4-81) + \tfrac{519}{673750\lambda_m^8}(I_1^5-243)\right] | |||
</math> | |||
We may alternatively express the Arruda–Boyce model in the form | |||
:<math> | |||
W = C_1~\sum_{i=1}^5 \alpha_i~\beta^{i-1}~(I_1^i-3^i) | |||
</math> | |||
where <math>\beta := \tfrac{1}{N} = \tfrac{1}{\lambda_m^2}</math> and | |||
<math> | |||
\alpha_1 := \tfrac{1}{2} ~;~~ \alpha_2 := \tfrac{1}{20} ~;~~ \alpha_3 := \tfrac{11}{1050} ~;~~ \alpha_4 := \tfrac{19}{7000} ~;~~ \alpha_5 := \tfrac{519}{673750}. | |||
</math> | |||
If the rubber is '''compressible''', a dependence on <math>J=\det(\boldsymbol{F})</math> can be introduced into the strain energy density; <math>\boldsymbol{F}</math> being the [[deformation gradient]]. Several possibilities exist, among which the Kaliske–Rothert<ref name=Kaliske>Kaliske, M. and Rothert, H., 1997, '''On the finite element implementation of rubber-like materials at finite strains''', Engineering Computations, 14(2), pp. 216–232.</ref> extension has been found to be reasonably accurate. With that extension, the Arruda-Boyce strain energy density function can be expressed as | |||
:<math> | |||
W = D_1\left(\tfrac{J^2-1}{2} - \ln J\right) + C_1~\sum_{i=1}^5 \alpha_i~\beta^{i-1}~(\overline{I}_1^i-3^i) | |||
</math> | |||
where <math>D_1</math> is a material constant and <math>\overline{I}_1 = {I}_1 J^{-2/3} </math> . For consistency with [[linear elasticity]], we must have <math>D_1 = \tfrac{\kappa}{2}</math> where <math>\kappa</math> is the [[bulk modulus]]. | |||
==Consistency condition== | |||
For the incompressible Arruda–Boyce model to be consistent with linear elasticity, with <math>\mu</math> as the [[shear modulus]] of the material, the [[Hyperelastic_material#Consistency_conditions_for_incompressible_I1_based_rubber_materials|following condition]] has to be satisfied: | |||
:<math> | |||
\cfrac{\partial W}{\partial I_1}\biggr|_{I_1=3} = \frac{\mu}{2} \,. | |||
</math> | |||
From the Arruda–Boyce strain energy density function, we have, | |||
:<math> | |||
\cfrac{\partial W}{\partial I_1} = C_1~\sum_{i=1}^5 i~\alpha_i~\beta^{i-1}~I_1^{i-1} \,. | |||
</math> | |||
Therefore, at <math>I_1 = 3</math>, | |||
:<math> | |||
\mu = 2C_1~\sum_{i=1}^5 i\,\alpha_i~\beta^{i-1}~I_1^{i-1} \,. | |||
</math> | |||
Substituting in the values of <math>\alpha_i</math> leads to the consistency condition | |||
:<math> | |||
\mu = C_1\left(1 + \tfrac{3}{5\lambda_m^2} + \tfrac{99}{175\lambda_m^4} + \tfrac{513}{875\lambda_m^6} + \tfrac{42039}{67375\lambda_m^8}\right) \,. | |||
</math> | |||
==Stress-deformation relations== | |||
The Cauchy stress for the incompressible Arruda–Boyce model is given by | |||
:<math> | |||
\boldsymbol{\sigma} = -p~\boldsymbol{\mathit{1}} + | |||
2~\cfrac{\partial W}{\partial I_1}~\boldsymbol{B} | |||
= -p~\boldsymbol{\mathit{1}} + 2C_1~\left[\sum_{i=1}^5 i~\alpha_i~\beta^{i-1}~I_1^{i-1}\right]\boldsymbol{B} | |||
</math> | |||
===Uniaxial extension=== | |||
[[Image:ArrudaHyperElastic.svg|thumb|350px|right|Stress-strain curves under uniaxial extension for Arruda–Boyce model compared with various hyperelastic material models.]] | |||
For uniaxial extension in the <math>\mathbf{n}_1</math>-direction, the [[finite strain theory|principal stretches]] are <math>\lambda_1 = \lambda,~ \lambda_2=\lambda_3</math>. From incompressibility <math>\lambda_1~\lambda_2~\lambda_3=1</math>. Hence <math>\lambda_2^2=\lambda_3^2=1/\lambda</math>. | |||
Therefore, | |||
:<math> | |||
I_1 = \lambda_1^2+\lambda_2^2+\lambda_3^2 = \lambda^2 + \cfrac{2}{\lambda} ~. | |||
</math> | |||
The [[finite strain theory|left Cauchy–Green deformation tensor]] can then be expressed as | |||
:<math> | |||
\boldsymbol{B} = \lambda^2~\mathbf{n}_1\otimes\mathbf{n}_1 + \cfrac{1}{\lambda}~(\mathbf{n}_2\otimes\mathbf{n}_2+\mathbf{n}_3\otimes\mathbf{n}_3) ~. | |||
</math> | |||
If the directions of the principal stretches are oriented with the coordinate basis vectors, we have | |||
:<math> | |||
\begin{align} | |||
\sigma_{11} & = -p + 2C_1\lambda^2\left[\sum_{i=1}^5 i~\alpha_i~\beta^{i-1}~I_1^{i-1}\right] \\ | |||
\sigma_{22} & = -p + \cfrac{2C_1}{\lambda}\left[\sum_{i=1}^5 i~\alpha_i~\beta^{i-1}~I_1^{i-1}\right] = \sigma_{33} ~. | |||
\end{align} | |||
</math> | |||
If <math>\sigma_{22} = \sigma_{33} = 0</math>, we have | |||
:<math> | |||
p = \cfrac{2C_1}{\lambda}\left[\sum_{i=1}^5 i~\alpha_i~\beta^{i-1}~I_1^{i-1}\right]~. | |||
</math> | |||
Therefore, | |||
:<math> | |||
\sigma_{11} = 2C_1\left(\lambda^2 - \cfrac{1}{\lambda}\right)\left[\sum_{i=1}^5 i~\alpha_i~\beta^{i-1}~I_1^{i-1}\right]~. | |||
</math> | |||
The [[stress (physics)|engineering strain]] is <math>\lambda-1\,</math>. The [[stress (physics)|engineering stress]] is | |||
:<math> | |||
T_{11} = \sigma_{11}/\lambda = | |||
2C_1\left(\lambda - \cfrac{1}{\lambda^2}\right)\left[\sum_{i=1}^5 i~\alpha_i~\beta^{i-1}~I_1^{i-1}\right]~. | |||
</math> | |||
===Equibiaxial extension=== | |||
For equibiaxial extension in the <math>\mathbf{n}_1</math> and <math>\mathbf{n}_2</math> directions, the [[finite strain theory|principal stretches]] are <math>\lambda_1 = \lambda_2 = \lambda\,</math>. From incompressibility <math>\lambda_1~\lambda_2~\lambda_3=1</math>. Hence <math>\lambda_3=1/\lambda^2\,</math>. | |||
Therefore, | |||
:<math> | |||
I_1 = \lambda_1^2+\lambda_2^2+\lambda_3^2 = 2~\lambda^2 + \cfrac{1}{\lambda^4} ~. | |||
</math> | |||
The [[finite strain theory|left Cauchy–Green deformation tensor]] can then be expressed as | |||
:<math> | |||
\boldsymbol{B} = \lambda^2~\mathbf{n}_1\otimes\mathbf{n}_1 + \lambda^2~\mathbf{n}_2\otimes\mathbf{n}_2+ \cfrac{1}{\lambda^4}~\mathbf{n}_3\otimes\mathbf{n}_3 ~. | |||
</math> | |||
If the directions of the principal stretches are oriented with the coordinate basis vectors, we have | |||
:<math> | |||
\sigma_{11} = 2C_1\left(\lambda^2 - \cfrac{1}{\lambda^4}\right)\left[\sum_{i=1}^5 i~\alpha_i~\beta^{i-1}~I_1^{i-1}\right] = \sigma_{22} ~. | |||
</math> | |||
The [[stress (physics)|engineering strain]] is <math>\lambda-1\,</math>. The [[stress (physics)|engineering stress]] is | |||
:<math> | |||
T_{11} = \cfrac{\sigma_{11}}{\lambda} = | |||
2C_1\left(\lambda - \cfrac{1}{\lambda^5}\right)\left[\sum_{i=1}^5 i~\alpha_i~\beta^{i-1}~I_1^{i-1}\right] = T_{22}~. | |||
</math> | |||
===Planar extension=== | |||
Planar extension tests are carried out on thin specimens which are constrained from deforming in one direction. For planar extension in the <math>\mathbf{n}_1</math> directions with the <math>\mathbf{n}_3</math> direction constrained, the [[finite strain theory|principal stretches]] are <math>\lambda_1=\lambda, ~\lambda_3=1</math>. From incompressibility <math>\lambda_1~\lambda_2~\lambda_3=1</math>. Hence <math>\lambda_2=1/\lambda\,</math>. | |||
Therefore, | |||
:<math> | |||
I_1 = \lambda_1^2+\lambda_2^2+\lambda_3^2 = \lambda^2 + \cfrac{1}{\lambda^2} + 1 ~. | |||
</math> | |||
The [[finite strain theory|left Cauchy–Green deformation tensor]] can then be expressed as | |||
:<math> | |||
\boldsymbol{B} = \lambda^2~\mathbf{n}_1\otimes\mathbf{n}_1 + \cfrac{1}{\lambda^2}~\mathbf{n}_2\otimes\mathbf{n}_2+ \mathbf{n}_3\otimes\mathbf{n}_3 ~. | |||
</math> | |||
If the directions of the principal stretches are oriented with the coordinate basis vectors, we have | |||
:<math> | |||
\sigma_{11} = 2C_1\left(\lambda^2 - \cfrac{1}{\lambda^2}\right)\left[\sum_{i=1}^5 i~\alpha_i~\beta^{i-1}~I_1^{i-1}\right] ~;~~ \sigma_{22} = 0 ~;~~ \sigma_{33} = 2C_1\left(1 - \cfrac{1}{\lambda^2}\right)\left[\sum_{i=1}^5 i~\alpha_i~\beta^{i-1}~I_1^{i-1}\right]~. | |||
</math> | |||
The [[stress (physics)|engineering strain]] is <math>\lambda-1\,</math>. The [[stress (physics)|engineering stress]] is | |||
:<math> | |||
T_{11} = \cfrac{\sigma_{11}}{\lambda} = | |||
2C_1\left(\lambda - \cfrac{1}{\lambda^3}\right)\left[\sum_{i=1}^5 i~\alpha_i~\beta^{i-1}~I_1^{i-1}\right]~. | |||
</math> | |||
===Simple shear=== | |||
The deformation gradient for a [[simple shear]] deformation has the form<ref name=Ogden>Ogden, R. W., 1984, '''Non-linear elastic deformations''', Dover.</ref> | |||
:<math> | |||
\boldsymbol{F} = \boldsymbol{1} + \gamma~\mathbf{e}_1\otimes\mathbf{e}_2 | |||
</math> | |||
where <math>\mathbf{e}_1,\mathbf{e}_2</math> are reference orthonormal basis vectors in the plane of deformation and the shear deformation is given by | |||
:<math> | |||
\gamma = \lambda - \cfrac{1}{\lambda} ~;~~ \lambda_1 = \lambda ~;~~ \lambda_2 = \cfrac{1}{\lambda} ~;~~ \lambda_3 = 1 | |||
</math> | |||
In matrix form, the deformation gradient and the left Cauchy–Green deformation tensor may then be expressed as | |||
:<math> | |||
\boldsymbol{F} = \begin{bmatrix} 1 & \gamma & 0 \\ 0 & 1 & 0 \\ 0 & 0 & 1 \end{bmatrix} ~;~~ | |||
\boldsymbol{B} = \boldsymbol{F}\cdot\boldsymbol{F}^T = \begin{bmatrix} 1+\gamma^2 & \gamma & 0 \\ \gamma & 1 & 0 \\ 0 & 0 & 1 \end{bmatrix} | |||
</math> | |||
Therefore, | |||
:<math> | |||
I_1 = \mathrm{tr}(\boldsymbol{B}) = 3 + \gamma^2 | |||
</math> | |||
and the Cauchy stress is given by | |||
:<math> | |||
\boldsymbol{\sigma} = -p~\boldsymbol{\mathit{1}} + 2C_1\left[\sum_{i=1}^5 i~\alpha_i~\beta^{i-1}~(3+\gamma^2)^{i-1}\right]~\boldsymbol{B} | |||
</math> | |||
==Statistical mechanics of polymer deformation== | |||
{{Main|Rubber elasticity}} | |||
The Arruda–Boyce model is based on the statistical mechanics of polymer chains. In this approach, each macromolecule is described as a chain of <math>N</math> segments, each of length <math>l</math>. If we assume that the initial configuration of a chain can be described by a [[random walk]], then the initial chain length is | |||
:<math> | |||
r_0 = l\sqrt{N} | |||
</math> | |||
If we assume that one end of the chain is at the origin, then the probability that a block of size <math>dx_1 dx_2 dx_3</math> around the origin will contain the other end of the chain, <math>(x_1,x_2,x_3)</math>, assuming a Gaussian [[probability density function]], is | |||
:<math> | |||
p(x_1,x_2,x_3) = \cfrac{b^3}{\pi^{3/2}}~\exp[-b^2(x_1^2 + x_2^2 + x_3^2)] ~;~~ b := \sqrt{\cfrac{3}{2Nl^2}} | |||
</math> | |||
The [[configurational entropy]] of a single chain from [[Boltzmann statistical mechanics]] is | |||
:<math> | |||
s = c -k_B b^2 r^2 | |||
</math> | |||
where <math>c</math> is a constant. The total entropy in a network of <math>n</math> chains is therefore | |||
:<math> | |||
\Delta S = -\tfrac{1}{2} n k_B (\lambda_1^2 + \lambda_2^2 + \lambda_3^2 - 3) = -\tfrac{1}{2} n k_B (I_1-3) | |||
</math> | |||
where an [[affine deformation]] has been assumed. Therefore the strain energy of the deformed network is | |||
:<math> | |||
W = -\theta \, dS = \tfrac{1}{2} n k_B \theta (I_1-3) | |||
</math> | |||
where <math>\theta</math> is the temperature. | |||
==Notes and references== | |||
<references/> | |||
==See also== | |||
* [[Hyperelastic material]] | |||
* [[Rubber elasticity]] | |||
* [[Finite strain theory]] | |||
* [[Continuum mechanics]] | |||
* [[Strain energy density function]] | |||
* [[Neo-Hookean solid]] | |||
* [[Mooney–Rivlin solid]] | |||
* [[Yeoh (hyperelastic model)]] | |||
* [[Gent (hyperelastic model)]] | |||
{{DEFAULTSORT:Arruda-Boyce Model}} | |||
[[Category:Continuum mechanics]] | |||
[[Category:Elasticity (physics)]] | |||
[[Category:Non-Newtonian fluids]] | |||
[[Category:Rubber properties]] | |||
[[Category:Solid mechanics]] | |||
[[Category:Polymer chemistry]] |
Latest revision as of 21:33, 25 July 2013
Template:Continuum mechanics In continuum mechanics, an Arruda–Boyce model[1] is a hyperelastic constitutive model used to describe the mechanical behavior of rubber and other polymeric substances. This model is based on the statistical mechanics of a material with a cubic representative volume element containing eight chains along the diagonal directions. The material is assumed to be incompressible.
The strain energy density function for the incompressible Arruda–Boyce model is given by[2]
where is the number of chain segments, is the Boltzmann constant, is the temperature in Kelvin, is the number of chains in the network of a cross-linked polymer,
where is the first invariant of the left Cauchy–Green deformation tensor, and is the inverse Langevin function which can approximated by
For small deformations the Arruda–Boyce model reduces to the Gaussian network based neo-Hookean solid model. It can be shown[3] that the Gent model is a simple and accurate approximation of the Arruda–Boyce model.
Alternative expressions for the Arruda–Boyce model
An alternative form of the Arruda–Boyce model, using the first five terms of the inverse Langevin function, is[4]
where is a material constant. The quantity can also be interpreted as a measure of the limiting network stretch.
If is the stretch at which the polymer chain network becomes locked, we can express the Arruda–Boyce strain energy density as
We may alternatively express the Arruda–Boyce model in the form
If the rubber is compressible, a dependence on can be introduced into the strain energy density; being the deformation gradient. Several possibilities exist, among which the Kaliske–Rothert[5] extension has been found to be reasonably accurate. With that extension, the Arruda-Boyce strain energy density function can be expressed as
where is a material constant and . For consistency with linear elasticity, we must have where is the bulk modulus.
Consistency condition
For the incompressible Arruda–Boyce model to be consistent with linear elasticity, with as the shear modulus of the material, the following condition has to be satisfied:
From the Arruda–Boyce strain energy density function, we have,
Substituting in the values of leads to the consistency condition
Stress-deformation relations
The Cauchy stress for the incompressible Arruda–Boyce model is given by
Uniaxial extension
For uniaxial extension in the -direction, the principal stretches are . From incompressibility . Hence . Therefore,
The left Cauchy–Green deformation tensor can then be expressed as
If the directions of the principal stretches are oriented with the coordinate basis vectors, we have
Therefore,
The engineering strain is . The engineering stress is
Equibiaxial extension
For equibiaxial extension in the and directions, the principal stretches are . From incompressibility . Hence . Therefore,
The left Cauchy–Green deformation tensor can then be expressed as
If the directions of the principal stretches are oriented with the coordinate basis vectors, we have
The engineering strain is . The engineering stress is
Planar extension
Planar extension tests are carried out on thin specimens which are constrained from deforming in one direction. For planar extension in the directions with the direction constrained, the principal stretches are . From incompressibility . Hence . Therefore,
The left Cauchy–Green deformation tensor can then be expressed as
If the directions of the principal stretches are oriented with the coordinate basis vectors, we have
The engineering strain is . The engineering stress is
Simple shear
The deformation gradient for a simple shear deformation has the form[6]
where are reference orthonormal basis vectors in the plane of deformation and the shear deformation is given by
In matrix form, the deformation gradient and the left Cauchy–Green deformation tensor may then be expressed as
Therefore,
and the Cauchy stress is given by
Statistical mechanics of polymer deformation
Mining Engineer (Excluding Oil ) Truman from Alma, loves to spend time knotting, largest property developers in singapore developers in singapore and stamp collecting. Recently had a family visit to Urnes Stave Church. The Arruda–Boyce model is based on the statistical mechanics of polymer chains. In this approach, each macromolecule is described as a chain of segments, each of length . If we assume that the initial configuration of a chain can be described by a random walk, then the initial chain length is
If we assume that one end of the chain is at the origin, then the probability that a block of size around the origin will contain the other end of the chain, , assuming a Gaussian probability density function, is
The configurational entropy of a single chain from Boltzmann statistical mechanics is
where is a constant. The total entropy in a network of chains is therefore
where an affine deformation has been assumed. Therefore the strain energy of the deformed network is
Notes and references
- ↑ Arruda, E. M. and Boyce, M. C., 1993, A three-dimensional model for the large stretch behavior of rubber elastic materials,, J. Mech. Phys. Solids, 41(2), pp. 389–412.
- ↑ Bergstrom, J. S. and Boyce, M. C., 2001, Deformation of Elastomeric Networks: Relation between Molecular Level Deformation and Classical Statistical Mechanics Models of Rubber Elasticity, Macromolecules, 34 (3), pp 614–626, 21 year-old Glazier James Grippo from Edam, enjoys hang gliding, industrial property developers in singapore developers in singapore and camping. Finds the entire world an motivating place we have spent 4 months at Alejandro de Humboldt National Park..
- ↑ Horgan, C.O. and Saccomandi, G., 2002, A molecular-statistical basis for the Gent constitutive model of rubber elasticity, Journal of Elasticity, 68(1), pp. 167–176.
- ↑ Hiermaier, S. J., 2008, Structures under Crash and Impact, Springer.
- ↑ Kaliske, M. and Rothert, H., 1997, On the finite element implementation of rubber-like materials at finite strains, Engineering Computations, 14(2), pp. 216–232.
- ↑ Ogden, R. W., 1984, Non-linear elastic deformations, Dover.