Structural Mechanics Modeling
T
he goal of this chapter is to give you an insight on how to approach the modeling of various structural mechanics problems.
Some physics interfaces and features discussed in this chapter are only available with certain products. For a detailed overview of the functionality available in each product, visit
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In this chapter:
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Study Types
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Selecting the Physics Interface
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Selecting Discretization
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Coupling Different Element Types
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Applying Loads
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Defining Constraints
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Calculating Reaction Forces
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Introduction to Material Models
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Modeling Piezoelectric Problems
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Modeling Electrostrictive and Ferroelectroelastic Materials
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Modeling Magnetostrictive Materials
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Mechanical Damping and Losses
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Modeling Geometric Nonlinearity
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Contact Modeling
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Activating and Deactivating Material
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Springs and Dampers
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Defining Multiphysics Models
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Thermally Coupled Problems
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Fluid–Structure Interaction
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Component Mode Synthesis
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Computing Mass Properties
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Effective Properties of Periodic Structures
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Modeling Pretensioned Bolts
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Simplified Modeling of Bolt Threads
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Modeling Embedded Structures and Reinforcements
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Modeling Thin Layers
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Modeling Cracks
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Buckling Analysis
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Performing a Random Vibration Analysis
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Performing a Response Spectrum Analysis
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Stress Linearization
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Solver Settings for Structural Mechanics
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Using Reduced Integration
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Result Presentation
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Part Libraries
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Parameter Estimation