Springs and Elastic Component / 1: |
Spring Constant / 1.1: |
Definition of the Spring / 1.1.1: |
Tangential Gradient / 1.1.2: |
System of Multiple Degrees of Freedom / 1.1.3: |
Elastic Component in a Vibration System / 1.2: |
Vibration Equations / 1.2.1: |
Chords of a Guitar / 1.2.2: |
Wave Equation / 1.2.3: |
First Stages of Analysis / 1.3: |
Orientation / 1.3.1: |
Steps of Analysis / 1.3.2: |
A Pitfall in the Approximate Solution / 1.3.3: |
Element Stiffness of Elastic Component / 1.3.4: |
One-Dimensional Combination of Components / 1.4: |
Coupling Between Components / 1.4.1: |
Generalized Matrix Equation for Coupled Elastic Components / 1.4.2: |
Verification of Boundary Condition Type / 1.4.3: |
Parallel Coupling of Elastic Components / 1.4.4: |
Transverse Stiffness of Elastic Components / 1.4.5: |
Plane Structures / 1.5: |
Transformation of Coordinates / 1.5.1: |
Obliquely Connected Components / 1.5.2: |
From Components to Finite Elements / 1.5.3: |
Outline of Finite Element Method (FEM) / 2: |
Fundamentals of Elasto-Plasticity Dynamics / 2.1: |
Viewpoint of Continuum Dynamics / 2.1.1: |
General Equations / 2.1.2: |
Basic Equations for Linear Elastic Body / 2.1.3: |
Principle of Virtual Work / 2.1.4: |
Expansion to Nonlinear Problems / 2.2: |
Geometrical Nonlinearity / 2.2.1: |
Material Nonlinearity / 2.2.2: |
Expansion to Dynamic Problems / 2.3: |
Mass and Damping Matrix / 2.3.1: |
Natural Frequency / 2.3.2: |
Simulation / 2.3.3: |
Spatial Discretization / 2.4: |
Derivating Procedure of Element Stiffness / 2.4.1: |
Stiffness of Truss Elements / 2.4.2: |
Element Stiffness of Plane Stress / 2.4.3: |
Element Stiffness of a Three-dimensional Elastic Body / 2.4.4: |
Role of Fem in Spring Analysis / 3: |
Comparison Of Fem With Conventional Design Meth- ODS / 3.1: |
Assumption in Model Construction / 3.1.1: |
From Linear to Nonlinear / 3.1.2: |
The Utilization of Fem Software / 3.2: |
Use of Commercial Software / 3.2.1: |
Selection of Commercial Software / 3.2.2: |
Development of Dedicated Programs / 3.2.3: |
Effectiveness in Design Practice / 3.3: |
Single Spring and Peripheral Parts / 3.3.1: |
Simulation of the Manufacturing Process / 3.3.2: |
Prospect of Future Application / 3.4: |
Optimum Design / 3.4.1: |
Nonlinear Problems in Manufacturing Simulation / 3.4.2: |
Necessity of Material Data / 3.4.3: |
Classification and Application of Element / 4: |
Introduction of Various Elements / 4.1: |
Beam Elements / 4.1.1: |
Plate Elements / 4.1.2: |
Axisymmetric Elements / 4.1.3: |
Cubic Elements (Solid Elements) / 4.1.4: |
Contact Elements / 4.1.5: |
Selection of Element and Discretizing Practice / 4.2: |
Selection of Elements / 4.2.1: |
Tips on Discretization / 4.2.2: |
Elementary Analysis / 5: |
Formed Wire Springs / 5.1: |
Stabilizer Bars / 5.2: |
Helical Compression Springs / 5.3: |
Static Analysis / 5.3.1: |
Analysis of Eigenvalue / 5.3.2: |
Helical Extension Springs / 5.4: |
Helical Torsion Springs / 5.5: |
Spiral Springs / 5.6: |
Leaf Springs / 5.7: |
Flat Springs / 5.8: |
Stress Concentration / 5.9: |
Stress Concentration on the Periphery of a Center Bolt Hole for Leaf Springs / 5.9.1: |
Stress Concentration at the Slit Bottom of a Disc Spring / 5.9.2: |
Stress Concentration at the End of a Torsion Bar Spring / 5.9.3: |
Expansion of Analytical Handling / 6: |
Tubular Stabilizer Bars / 6.1: |
Effect of Bush / 6.1.2: |
Problem of Contact / 6.2: |
Non-circular Cross Section / 6.2.2: |
Presetting / 6.2.3: |
Surging / 6.2.4: |
RBA Type Leaf Springs / 6.3: |
Effect of Shackle and Contact Plate / 6.3.2: |
Hysteresis Characteristic / 6.3.3: |
Wind-up / 6.3.4: |
Disc Springs, Ring Springs / 6.3.5: |
Disc Springs / 6.4.1: |
Ring Springs / 6.4.2: |
Index |
Springs and Elastic Component / 1: |
Spring Constant / 1.1: |
Definition of the Spring / 1.1.1: |
Tangential Gradient / 1.1.2: |
System of Multiple Degrees of Freedom / 1.1.3: |
Elastic Component in a Vibration System / 1.2: |