1 / 20

Theory of Elasticity

Theory of Elasticity. Theory of elasticity governs response S ymmetric stress & strain components Governing equations Equilibrium equations (3) Strain-displacement equations (6) Constitutive equations (6) Unknowns Stress (6) Strain (6) Displacement (3). Boundary & Initial Conditions.

neviah
Download Presentation

Theory of Elasticity

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Theory of Elasticity • Theory of elasticity governs response • Symmetric stress & strain components • Governing equations • Equilibrium equations (3) • Strain-displacement equations (6) • Constitutive equations (6) • Unknowns • Stress (6) • Strain (6) • Displacement (3)

  2. Boundary & Initial Conditions • Linear elastic material • Three partial differential equations in displacements • Second order in each coordinate • Second order in time • On a free surface in each direction • Specify stress or displacement but not both • Initial conditions for each direction specify • Displacement and velocity

  3. Surface Forces • Specify pressure (szz), shears (szx, szy) or • Specify displacements (u,v,w)

  4. Rigid Body Motion – 2D

  5. Rigid Body Displacements – 2D • Strains vanish • Integrating normal strains • Integrating shear strain • Hence (U, V are constants) • Displacement solution

  6. Reactions with Excessive Constraints Extra constraint in horizontal direction will add excessive stress Vertical constraints and loads produce point load infinite stresses

  7. Rigid Body Displacements – 3D • All strains vanish • In terms of displacements • Integrating yields displacements • Where • And

  8. Self-Equilibrating Forces • Examples include: • Uniform pressure (submarine or bathysphere) • Thermal expansion • BCs remove rigid body translations & rotations • Constrain six degrees of freedom (3 dofs at one point, 2 dofs at a second and 1 dof at a third)

  9. Plate & Beam Dofs at Each Node • Beam – 3 translations 3 rotations • Plate – 3 translations 2 rotations

  10. Nastran FE Code – Plate Elements • All nodes for all elements types have six dofs • 3 for translation • 3 for rotation • Flat plate models need dofs perpendicular to plane of model constrained (set to zero) • Shells made of plate elements do not • Solid elements need all three rotations at each node set to zero

  11. Simply Supported Beam Example Fix six dofs – 5 translation and 1 rotation

  12. Simply Supported Beam Example Fix six dofs – 5 translation and 1 rotation

  13. Cantilever Beam Fix six dofs – 3 translation and 3 rotation

  14. Internal Surfaces & Cracks • Cracks • Internal Surfaces

  15. Hertz Contact - Gaps & Friction • Hertz Contact • Gap & Friction Elements

  16. Transformations

  17. Use of Symmetry • Makes a large problem smaller • Axisymmetry reduces a 3D problem to 2D • Recall stress & strain symmetric • Examples:

  18. Periodic Boundary Conditions • Stress & Strain are periodic • Mean displacements can vary linearly with coordinates due to expansion and rotation • For

  19. Multi-Point Constraints - Tying or where xi are specified degrees of freedom, cij dj are known constants.

  20. Distant Boundary Conditions • Build a sufficiently large model • At least 20 times length of largest dimension of interest • Substructure a large coarse model • Use output from large model as input to a refined local model • Use super-elements or substructuring • Use infinite elements (when available)

More Related