Orthotropic material

Related lectures (32)

Explores orthotropic continuum damage models, stress-strain behavior, crack representation, and concrete simulation.

Covers hyperelasticity basics, including stress-strain response, energy density, and isotropic materials.

Explores effective elasticity through rigorous bounds for material properties and the minimization of total elastic energy in composites.

Explores higher-order finite elements, Lagrangian family, and digital integration for stiffness matrix evaluation.

Covers elasticity, deformation, stress-strain relationships, anisotropy, measurement methods, yield strength, and energy storage in materials.

Covers fracture mechanics fundamentals, including crack analysis and growth conditions.

Explores homogenization with Eshelby, analyzing multiple inclusions and effective moduli in composite materials.

Explains the shear stress and cutting force relationship based on Merchant's Law.

Explores the deformation of materials through stresses, deformations, and elasticity, focusing on the behavior of metals, ceramics, and polymers.

Covers the derivation of Hooke's law in 3D for isotropic materials and its applications in solving problems.

Explores a patient-specific knee model for evaluating patellar strain in TKA and its clinical implications.

Introduces the basics of linear elasticity, material functions, and stress-strain relationships in isotropic materials.

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