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ME-331: Solid mechanics
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Lectures in this course (36)
Plasticity: Bending of an Elastic-Perfectly-Plastic Beam
Covers the bending of an elastic-perfectly-plastic beam and its key characteristics.
Plasticity: The Taylor-Quinney Experiment
Discusses the Taylor-Quinney Experiment, uniaxial loading, torsion, effective stress, and hardening.
Plasticity: Engineering vs True Stress and Strain
Explores the conversion from engineering to true stress and strain measures, highlighting their impact on material behavior.
Linear Elasticity: Basics and Material Functions
Introduces the basics of linear elasticity, material functions, and stress-strain relationships in isotropic materials.
Linear Elasticity: Basics and Hooke's Law
Explores linear elasticity, Hooke's Law, isotropic materials, and thermal expansion effects.
Plasticity: Tensile Ductility
Explores plasticity, tensile ductility, stress-strain curves, radiation-induced embrittlement, and necking in materials.
Linear Elasticity: Equations of Linear Elasticity
Covers the equations of linear elasticity for static problems with small strain, emphasizing uniqueness of solutions and Navier's Equations.
Linear Elasticity: Thin Film on a Substrate
Explores stresses in thin films on substrates, discussing equal displacements, shear stresses, and practical applications in microelectronics.
Plasticity: Work Hardening and Plastic Strain Evolution
Explores the evolution of hardening and plastic strain in materials, emphasizing the relationship between stress increments and plastic strains.
Hyperelasticity: Basic Theory and Applications
Covers hyperelasticity basics, including stress-strain response, energy density, and isotropic materials.
Linear Elasticity: Channel Die Compression with Friction
Explores linear elasticity in confined compression with friction and stress distributions.
Hyperelasticity: Models for Hyperelastic Materials
Explores hyperelasticity, constitutive models, incompressibility, and stiffness response in isotropic materials.
Hyperelasticity: More Examples
Explores hyperelasticity through examples, focusing on the 'Channel Die Compression' problem and the behavior of Neo-Hookean materials.
Hyperelasticity: Recap and Application
Covers the stress-stretch relationship in hyperelasticity, incompressible materials, and solving boundary value problems, with an application in customizing sports shoe stiffness.
Hyperelasticity: Inflation of a Balloon
Explores hyperelasticity through the inflation of a balloon, discussing force balance, material behavior, and boundary conditions.
Hyperelasticity: Cavitation
Covers the expansion of a spherical void under external pressure and its implications.
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