MSC Marc 2018

Marc 2018 focused to further improve specific industry workflows, particularly for rubber and seal modeling. Additionally, the release provides advancements in contact analysis, multi-physics simulations, convergence control, solver interoperability, all tuned in for efficiency and quality.

Marc is a powerful and versatile nonlinear finite element analysis solution that accurately simulates the response of your products under static, dynamic, and multi-physics field loading scenarios. With Marc, you can solve manufacturing and product development problems with one solver in a single modeling environment.

Optimized for nonlinear analysis, Marc is a comprehensive and powerful solution for solving a wide range of problems throughout the product life cycle, including manufacturing process simulation, design performance analysis, workload performance, and failure analysis. Improvements include: incorporation of various forms of nonlinear analysis (materials, geometry, boundary conditions including contact)

Thermal analysis

Thermo-mechanical coupling analysis

Electromagnetic

Piezoelectric analysis

Electro-thermo-mechanical

Electrostatic, static magnetic and structural response coupling

Manufacturing processes such as sheet metal, hydroforming, extrusion, blow molding, welding, quenching, hardening, cutting, etc.

Marc's excellent, intuitive contact modeling capabilities allow you to study the interactions between multiple components. You can easily set up one-, two-, or three-dimensional contact models to analyze and visualize changing part interactions.

Modeling efficiency is improved by eliminating the need for additional contact elements, contact pairs, or master-slave definitions.

Self-contact can be set up and studied without additional modeling effort.

Friction effects and related material changes can be easily analyzed.

Choose from a large library of metallic and non-metallic material models and more than 200 structural, thermal, multiphysics, and fluid analysis primitives to accurately model the materials used in your design. Isotropic, Orthotropic Anisotropic and Anisotropic Elasticity

Isotropic and anisotropic plasticity

Hyperelasticity (elastic materials)

Behavior with and without changes in time

Metal powders, soils, concrete, notational alloys

Fiber welding, viscoplasticity, creep

Composite materials

Piezoelectric phenomena

User-defined material models

You can choose from a wide variety of failure models to study the deterioration and failure of metals, concrete, composites, and elastomers. Ductile damage

Damage accumulation in elastomers

Composite failure analysis

Laminate bond failure

Low Tension Rupture and Crush

Fracture mechanics

Crack extension under monotonic, low and high cyclic loading

User-defined failure models

Achieve greater accuracy with less modeling effort and ensure high mesh quality when dealing with large deformations with the help of automated mesh reformatting solutions. Automatic re-meshing of 2D and 3D models

User-specific guidelines for mesh control

Useful for manufacturing process simulation and self-contact analysis

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