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- Microplane_model_for_constitutive_laws_of_materials abstract "The microplane model, conceived in 1984, is a material constitutive model for progressive softening damage. Its advantage over the classical tensorial constitutive models is that it can capture the oriented nature of damage such as tensile cracking, slip, friction, and compression splitting, as well as the orientation of fiber reinforcement. Another advantage is that the anisotropy of materials such as gas shale or fiber composites can be effectively represented. To prevent unstable strain localization (and spurious mesh sensitivity in finite element computations), this model must be used in combination with some nonlocal continuum formulation (e.g., the crack band model). Prior to 2000, these advantages were outweighed by greater computational demands of the material subroutine, but thanks to huge increase of computer power, the microplane model is now routinely used in computer programs, even with tens of millions of finite elements.".
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- Microplane_model_for_constitutive_laws_of_materials wikiPageRevisionID "699788632".
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Anisotropy.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Category:Equations_of_physics.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Category:Materials_science.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Clay.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Concrete_fracture_analysis.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Constitutive_equation.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Deformation_(mechanics).
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Fiber_composite.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Finite_element_method.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Fracture.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Friction.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink G._I._Taylor.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Index_ellipsoid.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Infinitesimal_strain_theory.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Integral.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Materials_science.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Metal.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Normal_(geometry).
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Orthogonality.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Rock_(geology).
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Sand.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Stress_(mechanics).
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Stress_tensor.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Tensor.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Triaxial.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Variational_principle.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Vector_(mathematics_and_physics).
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLink Virtual_work.
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLinkText "Microplane model for constitutive laws of materials".
- Microplane_model_for_constitutive_laws_of_materials wikiPageWikiLinkText "microplane model for constitutive laws of materials".
- Microplane_model_for_constitutive_laws_of_materials wikiPageUsesTemplate Template:Dn.
- Microplane_model_for_constitutive_laws_of_materials wikiPageUsesTemplate Template:Orphan.
- Microplane_model_for_constitutive_laws_of_materials wikiPageUsesTemplate Template:Reflist.
- Microplane_model_for_constitutive_laws_of_materials subject Category:Equations_of_physics.
- Microplane_model_for_constitutive_laws_of_materials subject Category:Materials_science.
- Microplane_model_for_constitutive_laws_of_materials hypernym Model.
- Microplane_model_for_constitutive_laws_of_materials type Person.
- Microplane_model_for_constitutive_laws_of_materials comment "The microplane model, conceived in 1984, is a material constitutive model for progressive softening damage. Its advantage over the classical tensorial constitutive models is that it can capture the oriented nature of damage such as tensile cracking, slip, friction, and compression splitting, as well as the orientation of fiber reinforcement. Another advantage is that the anisotropy of materials such as gas shale or fiber composites can be effectively represented.".
- Microplane_model_for_constitutive_laws_of_materials label "Microplane model for constitutive laws of materials".
- Microplane_model_for_constitutive_laws_of_materials wasDerivedFrom Microplane_model_for_constitutive_laws_of_materials?oldid=699788632.
- Microplane_model_for_constitutive_laws_of_materials isPrimaryTopicOf Microplane_model_for_constitutive_laws_of_materials.