Nonlinear Structural Materials Module
Nonlinear Structural Materials Module
For Augmenting Structural Mechanics Analyses with Nonlinear Material Models
Add Hyperelastic, Elastoplastic, Viscoplastic, and Creep Material Models
The Nonlinear Structural Materials Module augments the mechanical capabilities of the Structural Mechanics Module and the MEMS Module with nonlinear material models, including large strain plastic deformation capabilities. When the mechanical stress in a structure becomes large, certain nonlinearities in the material properties force you to abandon linear material models. This situation also occurs in some operating conditions, such as high temperature. The Nonlinear Structural Materials Module adds elastoplastic, viscoplastic, creep, and hyperelastic material models.
User-defined material models based on stress or strain invariants, flow rules, and creep laws can easily be created directly in the user interface with the built-in constitutive laws as a starting point. You can both combine material models and include multiphysics effects. The tutorial models that accompany the module illustrate this by showcasing combined creep and plasticity, thermally induced creep and viscoplasticity, as well as orthotropic plasticity. The Nonlinear Structural Materials Module also has important applications where it is combined with the Fatigue Module and the Multibody Dynamics Module.
- A circular bar is subjected to a uniaxial tensile test, resulting in large deformations. The bar experiences large-scale necking and plastic deformation across its central cross-sectional region.
- Fluid flow, pressure field, and von Mises stresses in a peristaltic pump. The fluid-structure interaction is caused by the roller squeezing the tubing’s walls. Large deformations, contact, and the hyperelastic behavior of the tubing material are considered. The simulation is provided courtesy of Nagi Elabbasi, Veryst Engineering.
|Hyperelastic||Plasticity and Viscoplasticity||Creep|
|Blatz-Ko||Kinematic Plastic Hardening||Deviatoric|
|Damping||Isotropic Plastic Hardening||Garofalo (Hyperbolic Sine)|
|Gao||Large Strain Plasticity||Nabarro-Herring|
|Gent||Orthotropic Hill Plasticity||Norton|
|Large Strain Plasticity||Perfectly Plastic Hardening||Norton-Bailey|
|Mooney-Rivlin (two, five and nine parameters)||Thermal Expansion||Potential|
|Murnaghan||Tresca Yield Criterion||User-defined Creep|
|Ogden||von Mises Yield Criterion||Weertman|
|User-defined Hyperelastic Material|
Viscoplastic Creep in Solder Joints
This example studies viscoplastic creep in solder joints under thermal loading using the Anand viscoplasticity model, which is suitable for large, isotropic, viscoplastic deformations in combination with small elastic deformations. The model geometry includes two electronic components (chips) mounted on a circuit board by means of several ...
In this model you study the force-deflection relation of a car door seal made from a soft rubber material. The model uses a hyperelastic material model together with formulations that can account for the large deformations and contact conditions.
Sheet Metal Forming
This example is a NAFEMS validation model of a friction contact problem with an elastoplastic material model. A thin metal sheet is being forced into a die by a punch. Both the compressing displacement and the release of the punch are modeled in order to compute the forming angle (at the maximum punch displacement) and the angle after the ...
Necking of an Elastoplastic Metal Bar
A circular metal bar of elasto-plastic material with nonlinear isotropic hardening behavior is subjected to uniaxial tension. Affected by significant stresses the bar experiences high plasticity. The phenomenon of necking is captured and its growth is accurately simulated. The change in radius is in good agreement with results found other ...
Inflation of a Spherical Rubber Balloon
This model aims to investigate the inflation of a rubber balloon with different hyperelastic material models, and compare the results to analytical expressions. A controlled inflation could benefit clinical applications, cardiovascular research, and the medical device industry, thus the importance of understanding the hyperelastic behavior ...
Temperature-Dependent Plasticity in Pressure Vessel
This example demonstrates how to use temperature dependent materials within the Nonlinear Structural Materials Module. A large container holds pressurized hot water. Several pipes are attached to the pressure vessel. Those pipes can rapidly transfer cold water in case of an emergency cooling. The pressure vessel is made of carbon steel with an ...
This model simulates the insertion of a snap hook in its groove. Fasteners like this are common in the automotive industry, for example, in the control panel of a car. In this case it is important to know the force that must be applied in order to place the hook in the slot but also the force needed to remove it. From a numerical point of view, ...
Elastoacoustic Effect in Rail Steel
The elastoacoustic effect is a change in the speed of elastic waves that propagate in a structure undergoing static elastic deformations. The effect is used in many ultrasonic techniques for nondestructive testing of prestressed states within structures. This example model studies the elastoacoustic effect in steels typically used in railroad ...
Plastic Deformation During the Expansion of a Biomedical Stent
A stent is a wire-mesh tube used to open a coronary artery during angioplasty, a process for the removal or compression of plaque. Their design is of significance for percutaneous transluminal angioplasty with stenting. During this procedure, a stent is deployed into the blood vessel by means of a balloon. The expanded stent acts as a scaffold ...