ansys® customization: user programmable features your … · 2016. 12. 20. · ansys®...

ANSYS® Customization: User Programmable Features USERMAT: Implementation of an Anisotropic, Hyperelastic Material Law for Soft Biological Tissues Your Contact Person: Dr. –Ing. Ansgar Polley Phone: 0511-390603-11 E-Mail [email protected] Task In ANSYS, the User Programmable Features (UPF) are a very powerful tool for customizing and extending the program behavior. Besides UserFunctions, UserElements and a lot more, the programming of own material models is the most popular application. As an example, the implementation of a model for soft biological tissues is shown on the right side. Solution Human soft tissues often show a fiber reinforced (hyper-) elastic behavior. The reinforcement is due to the wavy structure of collagen fibrils. Fiber directions can be obtained from histological sec- tions. For arterial walls, Holzapfel [1] proposed an anisotropic strain energy function of the type ) ( ) , ( ) , ( ) , , , ( 6 4 2 1 02 01 J I I I I J vol aniso iso A A C introducing the structural tensors 02 02 02 01 01 01 , a a A a a A and extending the invariant basis according to 02 02 6 01 01 4 , , , A C a C A C a C I I A special form of the strain energy function aniso is used to account for the exponential fiber behavior in tension: 6 , 4 2 2 2 1 6 4 1 1 exp 2 ) , ( i i aniso I k k k I I The constitutive law allows each arterial layer to be modeled as a fiber reinforced composite with two independent fiber directions. The implementation in ANSYS was done by the USERMAT- interface and is based on the deformation gradi- ent F. By means of state variables, a detailed postprocessing is possible: matrix- and fiber stresses, fiber stretches et cetera. Benefit for the customer User defined materials allow a precise adaptation and a more realistic description of material behavior in numerical analysis. This is an attractive option if no standard material law can be applied. [1] Holzapfel, G.A.; Gasser, T.C.; Ogden, R.W.: A new constitutive framework for arterial wall mechanics and a comparative study of material models. Fig. 1: Components of an elastic arterial wall: In- tima, Media and Adventitia. Fig. 2: Elastic Behavior of an artery during clamping. Fig. 3: Raise of factor in axial stresses

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ANSYS® Customization: User Programmable Features

USERMAT: Implementation of an Anisotropic, Hyperelastic Material Law for Soft Biological Tissues

Your Contact Person: Dr. –Ing. Ansgar Polley Phone: 0511-390603-11 E-Mail [email protected]

Task In ANSYS, the User Programmable Features (UPF) are a very powerful tool for customizing and extending the program behavior. Besides UserFunctions, UserElements and a lot more, the programming of own material models is the most popular application. As an example, the imple-mentation of a model for soft biological tissues is shown on the right side.

Solution Human soft tissues often show a fiber reinforced (hyper-) elastic behavior. The reinforcement is due to the wavy structure of collagen fibrils. Fiber directions can be obtained from histological sec-tions. For arterial walls, Holzapfel [1] proposed an anisotropic strain energy function of the type

)(),(),(), , ,( 64210201 JIIIIJ volanisoiso AAC

introducing the structural tensors

020202010101 , aaAaaA

and extending the invariant basis according to

0202601014 , , , ACaCACaC II

A special form of the strain energy function aniso

is used to account for the exponential fiber be-havior in tension:

6,4

164 11exp

2),(

iianiso Ik

kII

The constitutive law allows each arterial layer to be modeled as a fiber reinforced composite with two independent fiber directions. The implemen-tation in ANSYS was done by the USERMAT-interface and is based on the deformation gradi-ent F. By means of state variables, a detailed postprocessing is possible: matrix- and fiber stresses, fiber stretches et cetera.

Benefit for the customer

User defined materials allow a precise adaptation and a more realistic description of material be-havior in numerical analysis. This is an attractive option if no standard material law can be applied.

[1] Holzapfel, G.A.; Gasser, T.C.; Ogden, R.W.: A new constitutive framework for arterial wall mechanics and a comparative study of material models.

Fig. 1: Components of an elastic arterial wall: In-tima, Media and Adventitia.

Fig. 2: Elastic Behavior of an artery during clamping.

Fig. 3: Raise of factor in axial stresses

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