Search Results - "Ductility"

Post-ductility : metals in architecture and engineering /

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Post-ductility : metals in architecture and engineering /

An electronic book accessible through the World Wide Web; click to view

Ductile shear zones : from micro- to macro-scales /

An electronic book accessible through the World Wide Web; click to view

Ductile shear zones : from micro- to macro-scales /

An electronic book accessible through the World Wide Web; click to view

A directory of arrhenius parameters : metals /

Subjects: “…Metals Ductility.…”
An electronic book accessible through the World Wide Web; click to view

A directory of arrhenius parameters : metals /

Subjects: “…Metals Ductility.…”
An electronic book accessible through the World Wide Web; click to view

Ductile-iron pipe and fittings

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Ductile-iron pipe and fittings

An electronic book accessible through the World Wide Web; click to view

Damage mechanics in metal forming advanced modeling and numerical simulation / by Saanouni, Khémais, 1955-

Table of Contents: “…Elements of continuum mechanics and thermodynamics -- Modeling of the thermomechanical behavior with ductile damage of metals -- Numerical methods for solving metal forming problems -- Applying metal forming processes to numerical -- Simulation.…”
An electronic book accessible through the World Wide Web; click to view

Damage mechanics in metal forming advanced modeling and numerical simulation / by Saanouni, Khémais, 1955-

Table of Contents: “…Elements of continuum mechanics and thermodynamics -- Modeling of the thermomechanical behavior with ductile damage of metals -- Numerical methods for solving metal forming problems -- Applying metal forming processes to numerical -- Simulation.…”
An electronic book accessible through the World Wide Web; click to view

Automotive alloys 1999 /

Table of Contents: “…-- Overview of Doe's programs on aluminum and magnesium for automotive applications -- ALCAR : a model for horizontal R & D consortia -- Innovative aluminum applications for automotive use in europe -- Mechanical surface treatments on high-strength magnesium alloys for fatigue life improvements -- Metallurgical characteristics of conductive heat resistance seam welds on aluminum sheet -- Producing steering wheel frames with an AIMg5Si2Mn-type alloy -- Ductility and formability of automotive AI alloy sheet -- Effect of Si on the ageing behaviour and formability of alloys based on AA6016 -- Microstructural strengthening in AI-Zn-Mg-Cu alloys used in automotive bumpers -- The role of natural aging on subsequent precipitation during the artificial aging of AA6111 aluminum alloy -- A process model for the age hardening of a 319-type aluminum alloy -- Observation of through-thickness deformation bands in an AI6111 alloy deformed in plane strain tension -- Texture evolution of a strip cast AA5XXX aluminum alloy during annealing -- Improvement of hot ductility in AI-Mg base alloys caused by small amounts of additional elements -- Optimised 6XXX aluminum alloy sheet for autobody outer panels -- Microchemistry and microstructural aspects leading to stress corrosion cracking in AA508 -- Ductility and bendability in 6000 series automotive alloys -- The effect of pre-aging on artificial aging response in AI-Mg-Si-Cu alloy 6111 -- Effects of minor Sc and Zr additions on commercial AI-Mg-Mn alloys -- Age hardening behavior in a commercial 319-type aluminum alloy -- The optimized tensile and fatigue properties of semi-solid 357 and modified 319 aluminum automotive parts -- Mechanisms of soldering in high pressure die casting of AI-11SiCu-Fe alloy -- Fiction stir welding magnesium alloys -- Roll forming technology for manufacturing axisymmetric automotive components - II: application to fabrication of AI V96Ts3 and 295 cast alloy wheels -- Optimisation of the quality of high pressure die cast magnesium alloys -- High-cycle fatigue crack initiation site distribution in A356.2.…”
An electronic book accessible through the World Wide Web; click to view

Automotive alloys 1999 /

Table of Contents: “…-- Overview of Doe's programs on aluminum and magnesium for automotive applications -- ALCAR : a model for horizontal R & D consortia -- Innovative aluminum applications for automotive use in europe -- Mechanical surface treatments on high-strength magnesium alloys for fatigue life improvements -- Metallurgical characteristics of conductive heat resistance seam welds on aluminum sheet -- Producing steering wheel frames with an AIMg5Si2Mn-type alloy -- Ductility and formability of automotive AI alloy sheet -- Effect of Si on the ageing behaviour and formability of alloys based on AA6016 -- Microstructural strengthening in AI-Zn-Mg-Cu alloys used in automotive bumpers -- The role of natural aging on subsequent precipitation during the artificial aging of AA6111 aluminum alloy -- A process model for the age hardening of a 319-type aluminum alloy -- Observation of through-thickness deformation bands in an AI6111 alloy deformed in plane strain tension -- Texture evolution of a strip cast AA5XXX aluminum alloy during annealing -- Improvement of hot ductility in AI-Mg base alloys caused by small amounts of additional elements -- Optimised 6XXX aluminum alloy sheet for autobody outer panels -- Microchemistry and microstructural aspects leading to stress corrosion cracking in AA508 -- Ductility and bendability in 6000 series automotive alloys -- The effect of pre-aging on artificial aging response in AI-Mg-Si-Cu alloy 6111 -- Effects of minor Sc and Zr additions on commercial AI-Mg-Mn alloys -- Age hardening behavior in a commercial 319-type aluminum alloy -- The optimized tensile and fatigue properties of semi-solid 357 and modified 319 aluminum automotive parts -- Mechanisms of soldering in high pressure die casting of AI-11SiCu-Fe alloy -- Fiction stir welding magnesium alloys -- Roll forming technology for manufacturing axisymmetric automotive components - II: application to fabrication of AI V96Ts3 and 295 cast alloy wheels -- Optimisation of the quality of high pressure die cast magnesium alloys -- High-cycle fatigue crack initiation site distribution in A356.2.…”
An electronic book accessible through the World Wide Web; click to view

Design against fracture and failure / by Huda, Zainul, Bulpett, Robert, Lee, K. Y. (Kang-Yong)

Table of Contents: “…Design against fatigue and ductile failures -- 11. Design against failures caused by temperature & environment.…”
An electronic book accessible through the World Wide Web; click to view

Design against fracture and failure / by Huda, Zainul, Bulpett, Robert, Lee, K. Y. (Kang-Yong)

Table of Contents: “…Design against fatigue and ductile failures -- 11. Design against failures caused by temperature & environment.…”
An electronic book accessible through the World Wide Web; click to view

Structural materials and engineering

Table of Contents: “…Murtagh -- Probabilistic modeling of cleavage fracture n the ductile-to-brittle transition region / Xiaosheng Gao -- Towards performance-based seismic design for buildings in Taiwan / Qiang Xue, Cheng-Chung Chen -- Recent advances in the design of industrial ground-floor slabs with special emphasis on permissible deformations / Ali A. …”
An electronic book accessible through the World Wide Web; click to view

Structural materials and engineering

Table of Contents: “…Murtagh -- Probabilistic modeling of cleavage fracture n the ductile-to-brittle transition region / Xiaosheng Gao -- Towards performance-based seismic design for buildings in Taiwan / Qiang Xue, Cheng-Chung Chen -- Recent advances in the design of industrial ground-floor slabs with special emphasis on permissible deformations / Ali A. …”
An electronic book accessible through the World Wide Web; click to view

Introduction to the explicit finite element method for nonlinear transient dynamics by Wu, Shen R., 1945-

Table of Contents: “…Machine generated contents note: PART 1 Fundamentals1 Introduction1.1 Era of Simulation and Computer Aided Engineering1.2 Preliminaries2 Framework of Explicit Finite Element Method for Nonlinear Transient Dynamics2.1 Transient Structural Dynamics2.2 Variational Principles for Transient Dynamics2.3 Finite Element Equations and the Explicit Procedures2.4 Main Features of the Explicit Finite Element Method2.5 Assessment of Explicit Finite Element MethodPART 2 Element Technology3 Four-Node Shell Element (Reissner-Mindlin Plate Theory)3.1 Fundamentals of Plates and Shells3.2 Linear Theory of R-M Plate3.3 Interpolation for Four-Node R-M Plate Element3.4 Reduced Integration and Selective Reduced Integration3.5 Perturbation Hourglass Control - Belytschko-Tsay (B-T) Element3.6 Physical Hourglass Control - Belytschko-Leviathan (B-L) (QPH) Element3.7 Shear Projection Method - Bathe-Dvorkin (B-D) Element3.8 Assessment of Four-Node R-M Plate Element4 Three-Node Shell Element (Reissner-Mindlin Plate Theory)4.1 Fundamentals of a Three-Node C0 Element4.2 Decomposition Method for C0 Triangular Element with One Point Integration4.3 Discrete Kirchhoff Triangular (DKT) Element4.4 Assessment of Three-Node R-M Plate Element5 Eight-Node Solid Element5.1 Trilinear Interpolation for the Eight-Node Hexahedron Element5.2 Locking Issues of the Eight-Node Solid Element5.3 One- Point Reduced Integration and the Perturbed Hourglass Control5.4 Assumed Strain Method and Selective / Reduced Integration5.5 Assumed Deviatoric Strain5.6 An Enhanced Assumed Strain Method5.7 Taylor Expansion of Assumed Strain about the Element Center5.8 Evaluation of Eight-Node Solid Element6 Two-Node Element6.1 Truss and Rod Element6.2 Timoshenko Beam Element6.3 Spring Element6.4 Spot Weld ElementPART 3 Material Models7 Material Model of Plasticity7.1 Fundamentals of Plasticity7.2 Constitutive Equations7.3 Software Implementation7.4 Evaluation of Shell Elements with Plastic Deformation8 Continuum Mechanics Model of Ductile Damage8.1 Concept of Damage Mechanics8.2 Gurson's Model8.3 Chow's Isotropic Model of Continuum Damage Mechanics8.4 Chow's Anisotropic Model of Continuum Damage Mechanics9 Models of Nonlinear Materials9.1 Vicoelasticity9.2 Polymer and Engineering Plastics9.3 Rubber9.4 Foam9.5 Honeycomb9.6 Laminated GlazingPART 4 Contact and Constraint Conditions10 Three-Dimensional Surface Contact10.1 Examples of Contact Problems10.2 Description of Contact Conditions10.3 Variational Principle for the Dynamic Contact Problem10.4 Penalty Method and the Regularization of Variational Inequality11 Numerical Procedures for Three-Dimensional Surface Contact11.1 A Contact Algorithm with Slave Node Searching Master Segment11.2 A Contact Algorithm with Master Segment Searching Slave Node11.3 Method of Contact Territory and Defense Node11.4 Pin- Ball Contact Algorithm11.5 Edge (Line Segment) Contact11.6 Evaluation of Contact Algorithm with Penalty Method12 Kinematic Constraint Conditions12.1 Rigid Wall12.2 Rigid Body12.3 Explicit Finite Element Procedure with Constraint Conditions12.4 Application Examples with Constraint Conditions.…”
An electronic book accessible through the World Wide Web; click to view

Introduction to the explicit finite element method for nonlinear transient dynamics by Wu, Shen R., 1945-

Table of Contents: “…Machine generated contents note: PART 1 Fundamentals1 Introduction1.1 Era of Simulation and Computer Aided Engineering1.2 Preliminaries2 Framework of Explicit Finite Element Method for Nonlinear Transient Dynamics2.1 Transient Structural Dynamics2.2 Variational Principles for Transient Dynamics2.3 Finite Element Equations and the Explicit Procedures2.4 Main Features of the Explicit Finite Element Method2.5 Assessment of Explicit Finite Element MethodPART 2 Element Technology3 Four-Node Shell Element (Reissner-Mindlin Plate Theory)3.1 Fundamentals of Plates and Shells3.2 Linear Theory of R-M Plate3.3 Interpolation for Four-Node R-M Plate Element3.4 Reduced Integration and Selective Reduced Integration3.5 Perturbation Hourglass Control - Belytschko-Tsay (B-T) Element3.6 Physical Hourglass Control - Belytschko-Leviathan (B-L) (QPH) Element3.7 Shear Projection Method - Bathe-Dvorkin (B-D) Element3.8 Assessment of Four-Node R-M Plate Element4 Three-Node Shell Element (Reissner-Mindlin Plate Theory)4.1 Fundamentals of a Three-Node C0 Element4.2 Decomposition Method for C0 Triangular Element with One Point Integration4.3 Discrete Kirchhoff Triangular (DKT) Element4.4 Assessment of Three-Node R-M Plate Element5 Eight-Node Solid Element5.1 Trilinear Interpolation for the Eight-Node Hexahedron Element5.2 Locking Issues of the Eight-Node Solid Element5.3 One- Point Reduced Integration and the Perturbed Hourglass Control5.4 Assumed Strain Method and Selective / Reduced Integration5.5 Assumed Deviatoric Strain5.6 An Enhanced Assumed Strain Method5.7 Taylor Expansion of Assumed Strain about the Element Center5.8 Evaluation of Eight-Node Solid Element6 Two-Node Element6.1 Truss and Rod Element6.2 Timoshenko Beam Element6.3 Spring Element6.4 Spot Weld ElementPART 3 Material Models7 Material Model of Plasticity7.1 Fundamentals of Plasticity7.2 Constitutive Equations7.3 Software Implementation7.4 Evaluation of Shell Elements with Plastic Deformation8 Continuum Mechanics Model of Ductile Damage8.1 Concept of Damage Mechanics8.2 Gurson's Model8.3 Chow's Isotropic Model of Continuum Damage Mechanics8.4 Chow's Anisotropic Model of Continuum Damage Mechanics9 Models of Nonlinear Materials9.1 Vicoelasticity9.2 Polymer and Engineering Plastics9.3 Rubber9.4 Foam9.5 Honeycomb9.6 Laminated GlazingPART 4 Contact and Constraint Conditions10 Three-Dimensional Surface Contact10.1 Examples of Contact Problems10.2 Description of Contact Conditions10.3 Variational Principle for the Dynamic Contact Problem10.4 Penalty Method and the Regularization of Variational Inequality11 Numerical Procedures for Three-Dimensional Surface Contact11.1 A Contact Algorithm with Slave Node Searching Master Segment11.2 A Contact Algorithm with Master Segment Searching Slave Node11.3 Method of Contact Territory and Defense Node11.4 Pin- Ball Contact Algorithm11.5 Edge (Line Segment) Contact11.6 Evaluation of Contact Algorithm with Penalty Method12 Kinematic Constraint Conditions12.1 Rigid Wall12.2 Rigid Body12.3 Explicit Finite Element Procedure with Constraint Conditions12.4 Application Examples with Constraint Conditions.…”
An electronic book accessible through the World Wide Web; click to view