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1.

図書

図書
sponsored by the Materials Division, ASME ; edited by S. Mall, K.M. Liechti, J.R. Vinson
出版情報: New York, N.Y. (345 E. 47th St., New York 10017) : ASME, c1988  v, 133 p. ; 28 cm
シリーズ名: MD ; vol. 6
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2.

図書

図書
sponsored by ASME Aerospace Division ; edited by D. Hui, J.R. Vinson
出版情報: New York, N.Y. : The Society, c1988  vi, 259 p. ; 28 cm
シリーズ名: AD (Series) ; vol. 13
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3.

図書

図書
sponsored by ASTM Committees D-30 on High Modulus Fibers and Their Composites and E-9 on Fatigue, Hampton, VA, 6-8 June 1983 ; Jack R. Vinson and Minoru Taya, editors
出版情報: Philadelphia, PA : ASTM, c1985  727 p. ; 24 cm
シリーズ名: ASTM special technical publication ; 864
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4.

図書

図書
J.R.Vinson, R.L.Sierakowski著 ; 福田博 [ほか] 訳
出版情報: 東京 : 日刊工業新聞社, 1987.12  xii, 278, viiip ; 22cm
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5.

図書

図書
by J.R. Vinson, R.L. Sierakowski
出版情報: Dordrecht ; Boston : M. Nijhoff, 1986  xi, 323 p. ; 25 cm
シリーズ名: Mechanics of structural systems ; 5
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目次情報: 続きを見る
Preface to the Second Edition
Preface to the First Edition
Introduction to Composite Materials / 1.:
General History / 1.1.:
Composite Material Description / 1.2.:
Types of Composite Materials / 1.3.:
Constituent Properties / 1.4.:
Composite Manufacturing, Fabrication and Processing / 1.5.:
Uses of Composite Materials / 1.6.:
Design and Analyses with Composite Materials / 1.7.:
References / 1.8.:
Journals / 1.9.:
Problems / 1.10.:
Anisotropic Elasticity and Composite Laminate Theory / 2.:
Introduction / 2.1.:
Derivation of the Anisotropic Elastic Stiffness and Compliance Matrices / 2.2.:
The Physical Meaning of the Components of the Orthotropic Elasticity Tensor / 2.3.:
Methods to Obtain Composite Elastic Properties from Fiber and Matrix Properties / 2.4.:
Thermal and Hygrothermal Considerations / 2.5.:
Time-Temperature Effects on Composite Materials / 2.6.:
High Strain Rate Effects on Material Properties / 2.7.:
Laminae of Composite Materials / 2.8.:
Laminate Analyses / 2.9.:
Piezoelectric Effects / 2.10.:
Plates and Panels of Composite Materials / 2.11.:
Plate Equilibrium Equations / 3.1.:
The Bending of Composite Material Laminated Plates: Classical Theory / 3.3.:
Classical Plate Theory Boundary Conditions / 3.4.:
Navier Solutions for Rectangular Composite Material Plates / 3.5.:
Navier Solution for a Uniformly Loaded Simply Supported Plate - An Example Problem / 3.6.:
Levy Solution for Plates of Composite Materials / 3.7.:
Perturbation Solutions for the Bending of a Composite Material Plate With Mid-Plane Symmetry and No Bending-Twisting Coupling / 3.8.:
Quasi-Isotropic Composite Panels Subjected to a Uniform Lateral Load / 3.9.:
A Static Analysis of Composite Material Panels Including Transverse Shear Deformation Effects / 3.10.:
Boundary Conditions for a Plate Using the Refined Plate Theory Which Includes Transverse Shear Deformation / 3.11.:
Composite Plates on an Elastic Foundation / 3.12.:
Solutions for Plates of Composite Materials Including Transverse-Shear Deformation Effects, Simply Supported on All Four Edges / 3.13.:
Dynamic Effects on Panels of Composite Materials / 3.14.:
Natural Flexural Vibrations of Rectangular Plates: Classical Theory / 3.15.:
Natural Flexural Vibrations of Composite Material Plate Including Transverse-Shear Deformation Effects / 3.16.:
Forced-Vibration Response of a Composite Material Plate Subjected to a Dynamic Lateral Load / 3.17.:
Buckling of a Rectangular Composite Material Plate--Classical Theory / 3.18.:
Buckling of a Composite Material Plate Including Transverse-Shear Deformation Effects / 3.19.:
Some Remarks on Composite Structures / 3.20.:
Methods of Analysis for Sandwich Panels With Composite Material Faces, and Their Structural Optimization / 3.21.:
Governing Equations for a Composite Material Plate With Mid-Plane Asymmetry / 3.22.:
Governing Equations for a Composite Material Plate With Bending-Twisting Coupling / 3.23.:
Concluding Remarks / 3.24.:
Problems and Exercises / 3.25.:
Beams, Columns and Rods of Composite Materials / 4.:
Development of Classical Beam Theory / 4.1.:
Some Composite Beam Solutions / 4.2.:
Composite Beams With Abrupt Changes in Geometry or Load / 4.3.:
Solutions by Green's Functions / 4.4.:
Composite Beams of Continuously Varying Cross-Section / 4.5.:
Rods / 4.6.:
Vibration of Composite Beams / 4.7.:
Beams With Mid-Plane Asymmetry / 4.8.:
Advanced Beam Theory for Dynamic Loading Including Mid-Plane Asymmetry / 4.9.:
Advanced Beam Theory Including Transverse Shear Deformation Effects / 4.10.:
Buckling of Composite Columns / 4.11.:
Composite Material Shells / 4.12.:
Analysis of Composite Material Circular Cylindrical Shells / 5.1.:
Some Edge Load and Particular Solutions / 5.3.:
A General Solution for Composite Cylindrical Shells Under Axially Symmetric Loads / 5.4.:
Response of a Long Axi-Symmetric Laminated Composite Shell to an Edge Displacement / 5.5.:
Sample Solutions / 5.6.:
Mid-Plane Asymmetric Circular Cylindrical Shells / 5.7.:
Buckling of Circular Cylindrical Shells of Composite Materials Subjected to Various Loads / 5.8.:
Vibrations of Composite Shells / 5.9.:
Additional Reading On Composite Shells / 5.10.:
Energy Methods For Composite Material Structures / 5.11.:
Theorem of Minimum Potential Energy / 6.1.:
Analysis of a Beam Using the Theorem of Minimum Potential Energy / 6.3.:
Use of Minimum Potential Energy for Designing a Composite Electrical Transmission Tower / 6.4.:
Minimum Potential Energy for Rectangular Plates / 6.5.:
A Rectangular Composite Material Plate Subjected to Lateral and Hygrothermal Loads / 6.6.:
In-Plane Shear Strength Determination of Composite Materials in Laminated Composite Panels / 6.7.:
Use of the Theorem of Minimum Potential Energy to Determine Buckling Loads in Composite Plates / 6.8.:
Trial Functions for Various Boundary Conditions for Composite Material Rectangular Plates / 6.9.:
Reissner's Variational Theorem and its Applications / 6.10.:
Static Deformation of Moderately Thick Beams / 6.11.:
Flexural Vibrations of Moderately Thick Beams / 6.12.:
Flexural Natural Frequencies of a Simply Supported Beam Including Transverse Shear Deformation and Rotatory Inertia Effects / 6.13.:
Strength and Failure Theories / 6.14.:
Failure of Monolithic Isotropic Materials / 7.1.:
Anisotropic Strength and Failure Theories / 7.3.:
Maximum Stress Theory / 7.3.1.:
Maximum Strain Theory / 7.3.2.:
Interactive Failure Theories / 7.3.3.:
Lamina Strength Theories / 7.4.:
Laminate Strength Analysis / 7.5.:
Joining of Composite Material Structures / 7.6.:
General Remarks / 8.1.:
Adhesive Bonding / 8.2.:
Mechanical Fastening / 8.3.:
Recommended Reading / 8.4.:
Introduction to Composite Design / 8.5.:
Structural Composite Design Procedures / 9.1.:
Engineering Analysis / 9.3.:
Appendices
Micromechanics / A-1:
Test Standards for Polymer Matrix Composites / A-2:
Properties of Various Polymer Composites / A-3:
Author Index
Subject Index
Preface to the Second Edition
Preface to the First Edition
Introduction to Composite Materials / 1.:
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