Difference between revisions of "Methods for Solving Elasticity Problems"

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Students who have completed the course should be able to use analytical methods of mathematical physics, offer models for solving problems in the professional field and justify the necessity and restrictions of their application.
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Theory of Elasticity: Kinematics of solid: The concept of the continuum media and the Lagrange and Euler approaches to the description of its movement; Material derivative of vector and tensor; Strain measures and tensors; Infinitesimal strain tensor and vector of small rotation. Dynamics of solid: Conservation of mass law; Classification of forces acting on the material body; Integral laws of the dynamics; Cauchy’s formula for the stress vector; Stress tensor; Differential equations of the deformable body dynamics. Thermodynamics of solid: First law of thermodynamics in integral and differential forms; Second law of thermodynamics in form of Clausius-Duhem inequality; Universal dissipative inequality; Third law of thermodynamics. Constitutive equations theory elements: Influential parameters, thermomechanical processes and constitutive equations; Material objectivity principle; Isotropic materials; Constitutive equations of isotropic thermoelastic material; Constitutive equations of viscous material; Constitutive equations of ideal plastic material. Constitutive equations in linear mechanics of solid: Classical constitutive equations of form changing processes: elastic material, viscous material, plastic material; Rheological models principle; Kelvin-Voigth material; Maxwell material; Standard linear viscous-elastic material; Ideal elastic-plastic material; Elastic- plastic material with linear hardening; Viscous-elastic-plastic material of Bingham. Basic equations of linear elasticity theory: Closed system of equations and boundary conditions for coupled thermal- elastic problem; Various forms of Hook’s law; Theory of elasticity equations in displacements; Theory of elasticity equations in terms of stresses; Beltrami-Mitchell equations; Theory of elasticity equations and boundary conditions in Pobedria form.
  
 
back to [[IMDP| International MSc program "Mechanics and Mathematical Modeling"]]
 
back to [[IMDP| International MSc program "Mechanics and Mathematical Modeling"]]

Latest revision as of 14:39, 15 February 2021

Theory of Elasticity: Kinematics of solid: The concept of the continuum media and the Lagrange and Euler approaches to the description of its movement; Material derivative of vector and tensor; Strain measures and tensors; Infinitesimal strain tensor and vector of small rotation. Dynamics of solid: Conservation of mass law; Classification of forces acting on the material body; Integral laws of the dynamics; Cauchy’s formula for the stress vector; Stress tensor; Differential equations of the deformable body dynamics. Thermodynamics of solid: First law of thermodynamics in integral and differential forms; Second law of thermodynamics in form of Clausius-Duhem inequality; Universal dissipative inequality; Third law of thermodynamics. Constitutive equations theory elements: Influential parameters, thermomechanical processes and constitutive equations; Material objectivity principle; Isotropic materials; Constitutive equations of isotropic thermoelastic material; Constitutive equations of viscous material; Constitutive equations of ideal plastic material. Constitutive equations in linear mechanics of solid: Classical constitutive equations of form changing processes: elastic material, viscous material, plastic material; Rheological models principle; Kelvin-Voigth material; Maxwell material; Standard linear viscous-elastic material; Ideal elastic-plastic material; Elastic- plastic material with linear hardening; Viscous-elastic-plastic material of Bingham. Basic equations of linear elasticity theory: Closed system of equations and boundary conditions for coupled thermal- elastic problem; Various forms of Hook’s law; Theory of elasticity equations in displacements; Theory of elasticity equations in terms of stresses; Beltrami-Mitchell equations; Theory of elasticity equations and boundary conditions in Pobedria form.

back to International MSc program "Mechanics and Mathematical Modeling"