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010   $a9786611051822
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100   $a20060331d2006      uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aTheory of plasticity$b[electronic resource] /$fJ. Chakrabarty
205   $a3rd ed.
210   $aAmsterdam ;$aBoston ;$aOxford $cElsevier/Butterworth-Heinemann$d2006
215   $a1 online resource (895 p.)
300   $aDescription based upon print version of record.
311   $a0-7506-6638-2 
320   $aIncludes bibliographical references and indexes.
327   $aFront Cover; Theory of Plasticity; Copyright Page; Table of Contents; Dedication; Preface to the third edition; Preface to the first edition; Chapter 1. Stresses and Strains; 1.1 Introduction; 1.2 The Stress-Strain Behavior; 1.3 Analysis of Stress; 1.4 Mohr's Representation of Stress; 1.5 Analysis of Strain Rate; 1.6 Concepts of Stress Rate; Problems; Chapter 2. Foundations of Plasticity; 2.1 The Criterion of Yielding; 2.2 Strain-Hardening Postulates; 2.3 The Rule of Plastic Flow; 2.4 Particular Stress-Strain Relations; 2.5 The Total Strain Theory; 2.6 Theorems of Limit Analysis
327   $a2.7 Uniqueness Theorems2.8 Extremum Principles; Problems; Chapter 3. Elastoplastic Bending and Torsion; 3.1 Plane Strain Compression and Bending; 3.2 Cylindrical Bars Under Torsion and Tension; 3.3 Thin-Walled Tubes Under Combined Loading; 3.4 Pure Bending of Prismatic Beams; 3.5 Bending of Beams Under Transverse Loads; 3.6 Torsion of Prismatic Bars; 3.7 Torsion of Bars of Variable Diameter; 3.8 Combined Bending and Twisting of Bars; Problems; Chapter 4. Plastic Analysis of Beams and Frames; 4.1 Introduction; 4.2 Limit Analysis of Beams; 4.3 Limit Analysis of Plane Frames
327   $a4.4 Displacements in Plane Frames4.5 Variable Repeated Loading; 4.6 Minimum Weight Design; 4.7 Influence of Axial Forces; 4.8 Limit Analysis of Space Frames; Problems; Chapter 5. Further Solutions of Elastoplastic Problems; 5.1 Expansion of a Thick Spherical Shell; 5.2 Expansion of a Thick-Walled Tube; 5.3 Thermal Stresses in a Thick-Walled Tube; 5.4 Thermal Stresses in a Thick Spherical Shell; 5.5 Pure Bending of a Curved Bar; 5.6 Rotating Discs and Cylinders; 5.7 Infinite Plate with a Circular Hole; 5.8 Yielding Around a Cylindrical Cavity; Problems; Chapter 6. Theory of the Slipline Field
327   $a6.1 Formulation of the Plane Strain Problem6.2 Properties of Slipline Fields and Hodographs; 6.3 Stress Discontinuities in Plane Strain; 6.4 Construction of Slipline Fields and Hodographs; 6.5 Analytical and Matrix Methods of Solution; 6.6 Explicit Solutions for Direct Problems; 6.7 Some Mixed Boundary-Value Problems; 6.8 Superposition of Slipline Fields; Problems; Chapter 7. Steady Problems in Plane Strain; 7.1 Symmetrical Extrusion Through Square Dies; 7.2 Unsymmetrical and Multihole Extrusion; 7.3 Sheet Drawing Through Tapered Dies; 7.4 Extrusion Through Tapered Dies
327   $a7.5 Extrusion Through Curved Dies7.6 Ideal Die Profiles in Drawing and Extrusion; 7.7 Limit Analysis of Plane Strain Extrusion; 7.8 Cold Rolling of Strips; 7.9 Analysis of Hot Rolling; 7.10 Mechanics of Machining; Problems; Chapter 8. Nonsteady Problems in Plane Strain; 8.1 Indentation by a Flat Punch; 8.2 Indentation by a Rigid Wedge; 8.3 Compression of a Wedge by a Flat Die; 8.4 Cylindrical Depression in a Large Block; 8.5 Compression Between Smooth Platens; 8.6 Compression Between Rough Platens; 8.7 Yielding of Notched Bars in Tension; 8.8 Bending of Single-Notched Bars
327   $a8.9 Bending of Double-Notched Bars
330   $aPlasticity is concerned with the mechanics of materials deformed beyond their elastic limit. A strong knowledge of plasticity is essential for engineers dealing with a wide range of engineering problems, such as those encountered in the forming of metals, the design of pressure vessels, the mechanics of impact, civil and structural engineering, as well as the understanding of fatigue and the economical design of structures. Theory of Plasticity is the most comprehensive reference on the subject as well as the most up to date -- no other significant Plasticity reference has been
606   $aPlasticity
606   $aMaterials$xMechanical properties
615  0$aPlasticity.
615  0$aMaterials$xMechanical properties.
676   $a620.11233
700   $aChakrabarty$b J$030761
712 02$aScienceDirect (Servicio en línea)
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910784451103321
996   $aTHEORY OF PLASTICITY$9319139
997   $aUNINA