Machine Design and Mechanisms

5.

Dynamics of Machinery

5.1.

5.1.1.

Static Force Analysis

5.1.1.1.

Free-Body Diagrams

5.1.1.2.

Equilibrium Equations

5.1.1.3.

Method of Joints

5.1.1.4.

Method of Sections

5.1.2.

Dynamic Force Analysis

5.1.2.1.

D'Alembert's Principle

5.1.2.2.

Inertia Forces and Torques

5.1.2.3.

Newton's Second Law Applications

5.1.3.

Principle of Superposition

5.1.3.1.

Application in Force Analysis

5.1.3.2.

5.2.

Engine Dynamics

5.2.1.

Single-Cylinder Engines

5.2.1.1.

5.2.1.2.

5.2.1.3.

Turning Moment Diagrams

5.2.2.

Multi-Cylinder Engines

5.2.2.1.

5.2.2.2.

Primary and Secondary Forces

5.2.2.3.

Balancing Conditions

5.3.

Flywheel Design

5.3.1.

Fluctuation of Energy and Speed

5.3.1.1.

Energy Storage in Flywheels

5.3.1.2.

Applications in Machinery

5.3.1.3.

Energy Diagrams

5.3.2.

Coefficient of Fluctuation

5.3.2.1.

Definition and Calculation

5.3.2.2.

Significance in Design

5.3.3.

Flywheel Sizing

5.3.3.1.

Mass Moment of Inertia

5.3.3.2.

Material Selection

5.3.3.3.

Stress Analysis

5.3.3.4.

Safety Considerations

5.4.

Balancing of Machinery

5.4.1.

Static Balancing

5.4.1.1.

Single-Plane Balancing

5.4.1.2.

Balancing Machines

5.4.1.3.

Field Balancing

5.4.2.

Dynamic Balancing

5.4.2.1.

Multi-Plane Balancing

5.4.2.2.

Balancing Procedures

5.4.2.3.

Influence Coefficient Method

5.4.3.

Balancing of Rotating Masses

5.4.3.1.

Calculation Methods

5.4.3.2.

Correction Techniques

5.4.3.3.

Balancing Quality Standards

5.4.4.

Balancing of Reciprocating Masses

5.4.4.1.

Primary and Secondary Forces

5.4.4.2.

Balancing in Engines

5.4.4.3.

Partial Balancing

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4. Design and Analysis of Specific Mechanisms

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6. Vibrations in Machinery