Mechanical design of machine components. (2016)
- Record Type:
- Book
- Title:
- Mechanical design of machine components. (2016)
- Main Title:
- Mechanical design of machine components
- Further Information:
- Note: Author, Ansel C. Ugural.
- Authors:
- Ugural, A. C
- Contents:
- BASICS; ; Introduction; Scope of the Book; Mechanical Engineering Design; Design Process; Design Analysis; Problem Formulation and Computation; Factor of Safety and Design Codes; Units and Conversion; Loading Classes and Equilibrium; Free-Body Diagrams and Load Analysis; Case Studies in Engineering; Work, Energy, and Power; Stress Components; Normal and Shear Strains; Problems; ; Materials ; Introduction; Material Property Definitions; Static Strength; Hooke’s Law and Modulus of Elasticity; Generalized Hooke’s Law; Volume Change; Thermal Stress–Strain Relations; Temperature and Stress–Strain Properties; Moduli of Resilience and Toughness; Dynamic and Thermal Effects; Hardness; Processes to Improve Hardness and the Strength of Metals; General Properties of Metals; General Properties of Nonmetals; Selecting Materials; Problems; ; Stress and Strain ; Introduction; Stresses in Axially Loaded Members; Direct Shear Stress and Bearing Stress; Thin-Walled Pressure Vessels; Stress in Members in Torsion; Shear and Moment in Beams; Stresses in Beams; Design of Beams; Plane Stress; Combined Stresses; Plane Strain; Measurement of Strain; Strain Rosette; Stress-Concentration Factors; Importance of Stress-Concentration Factors in Design; Three-Dimensional Stress; Equations of Equilibrium for Stress; Strain–Displacement Relations: Exact Solutions; Problems; ; Deflection and Impact ; Introduction; Deflection of Axially Loaded Members; Angle of Twist of Shafts; Deflection of Beams byBASICS; ; Introduction; Scope of the Book; Mechanical Engineering Design; Design Process; Design Analysis; Problem Formulation and Computation; Factor of Safety and Design Codes; Units and Conversion; Loading Classes and Equilibrium; Free-Body Diagrams and Load Analysis; Case Studies in Engineering; Work, Energy, and Power; Stress Components; Normal and Shear Strains; Problems; ; Materials ; Introduction; Material Property Definitions; Static Strength; Hooke’s Law and Modulus of Elasticity; Generalized Hooke’s Law; Volume Change; Thermal Stress–Strain Relations; Temperature and Stress–Strain Properties; Moduli of Resilience and Toughness; Dynamic and Thermal Effects; Hardness; Processes to Improve Hardness and the Strength of Metals; General Properties of Metals; General Properties of Nonmetals; Selecting Materials; Problems; ; Stress and Strain ; Introduction; Stresses in Axially Loaded Members; Direct Shear Stress and Bearing Stress; Thin-Walled Pressure Vessels; Stress in Members in Torsion; Shear and Moment in Beams; Stresses in Beams; Design of Beams; Plane Stress; Combined Stresses; Plane Strain; Measurement of Strain; Strain Rosette; Stress-Concentration Factors; Importance of Stress-Concentration Factors in Design; Three-Dimensional Stress; Equations of Equilibrium for Stress; Strain–Displacement Relations: Exact Solutions; Problems; ; Deflection and Impact ; Introduction; Deflection of Axially Loaded Members; Angle of Twist of Shafts; Deflection of Beams by Integration; Beam Deflections by Superposition; Beam Deflection by the Moment-Area Method; Impact Loading; Longitudinal and Bending Impact; Torsional Impact; Bending of Thin Plates; Deflection of Plates by Integration; Problems; ; Energy Methods and Stability ; Introduction; Strain Energy in Common Members; Work–Energy Method; Castigliano’s Theorem; Statically Indeterminate Problems; Virtual Work Principle; Use of Trigonometric Series in Energy Methods; Buckling of Columns; Critical Stress in a Column; Initially Curved Columns; Eccentric Loads and the Secant Formula; Design Formulas for Columns; Beam–Columns; Energy Methods Applied to Buckling; Buckling of Rectangular Plates; Problems; ; FAILURE PREVENTION; ; Static Failure Criteria and Reliability ; Introduction; Introduction to Fracture Mechanics; Stress–Intensity Factors; Fracture Toughness; Yield and Fracture Criteria; Maximum Shear Stress Theory; Maximum Distortion Energy Theory; Octahedral Shear Stress Theory; Comparison of the Yielding Theories; Maximum Principal Stress Theory; Mohr’s Theory; Coulomb–Mohr Theory; Reliability; Normal Distributions; Reliability Method and Margin of Safety; Problems; ; Fatigue Failure Criteria ; Introduction; Nature of Fatigue Failures; Fatigue Tests; S–N Diagrams; Estimating the Endurance Limit and Fatigue Strength; Modified Endurance Limit; Endurance Limit Reduction Factors; Fluctuating Stresses; Theories of Fatigue Failure; Comparison of the Fatigue Criteria; Design for Simple Fluctuating Loads; Design for Combined Fluctuating Loads; Prediction of Cumulative Fatigue Damage; Fracture Mechanics Approach to Fatigue; Problems; ; Surface Failure ; Introduction; Corrosion; Friction; Wear; Wear Equation; Contact-Stress Distributions; Spherical and Cylindrical Surfaces in Contact; Maximum Stress in General Contact; Surface-Fatigue Failure; Prevention of Surface Damage; Problems; ; APPLICATIONS; ; Shafts and Associated Parts ; Introduction; Materials Used for Shafting; Design of Shafts in Steady Torsion; Combined Static Loadings on Shafts; Design of Shafts for Fluctuating and Shock Loads; Interference Fits; Critical Speed of Shafts; Mounting Parts; Stresses in Keys; Splines; Couplings; Universal Joints; Problems; ; Bearings and Lubrication ; Introduction; Lubricants; Types of Journal Bearings; Forms of Lubrication; Lubricant Viscosity; Petroff’s Bearing Equation; Hydrodynamic Lubrication Theory; Design of Journal Bearings; Lubricant Supply to Journal Bearings; Heat Balance of Journal Bearings; Materials for Journal Bearings; Types and Dimensions of Rolling Bearings; Rolling Bearing Life; Equivalent Radial Load; Selection of Rolling Bearings; Materials and Lubricants of Rolling Bearings; Mounting and Closure of Rolling Bearings; Problems; ; Spur Gears ; Introduction; Geometry and Nomenclature; Fundamentals; Gear Tooth Action and Systems of Gearing; Contact Ratio and Interference; Gear Trains; Transmitted Load; Bending Strength of a Gear Tooth: The Lewis Formula; Design for the Bending Strength of a Gear Tooth: The AGMA Method; Wear Strength of a Gear Tooth: The Buckingham Formula; Design for the Wear Strength of a Gear Tooth: The AGMA Method; Materials for Gears; Gear Manufacturing; Problems; ; Helical, Bevel, and Worm Gears ; Introduction; Helical Gears; Helical Gear Geometry; Helical Gear Tooth Loads; Helical Gear Tooth Bending and Wear Strengths; Bevel Gears; Tooth Loads of Straight Bevel Gears; Bevel Gear Tooth Bending and Wear Strengths; Worm Gearsets; Worm Gear Bending and Wear Strengths; Thermal Capacity of Worm Gearsets; Problems; ; Belts, Chains, Clutches, and Brakes ; Introduction; Belts; Belt Drives; Belt Tension Relationships; Design of V-Belt Drives; Chain Drives; Common Chain Types; Materials for Brakes and Clutches; Internal Expanding Drum Clutches and Brakes; Disk Clutches and Brakes; Cone Clutches and Brakes; Band Brakes; Short-Shoe Drum Brakes; Long-Shoe Drum Brakes; Energy Absorption and Cooling; Problems; ; Mechanical Springs ; Introduction; Torsion Bars; Helical Tension and Compression Springs; Spring Materials; Helical Compression Springs; Buckling of Helical Compression Springs; Fatigue of Springs; Design of Helical Compression Springs for Fatigue Loading; Helical Extension Springs; Torsion Springs; Leaf Springs; Miscellaneous Springs; Problems; ; Power Screws, Fasteners, and Connections ; Introduction; Standard Thread Forms; Mechanics of Power Screws; Overhauling and Efficiency of Power Screws; Ball Screws; Threaded Fastener Types; Stresses in Screws; Bolt Tightening and Preload; Tension Joints under Static Loading; Gasketed Joints; Determining the Joint Stiffness Constants; Tension Joints under Dynamic Loading; Riveted and Bolted Joints Loaded in Shear; Shear of Rivets or Bolts due to Eccentric Loading; Welding; Welded Joints Subjected to Eccentric Loading; Brazing and Soldering; Adhesive Bonding; Problems; ; Miscellaneous Machine Components ; Introduction; Basic Relations; Thick-Walled Cylinders under Pressure; Compound Cylinders: Press or Shrink Fits; Disk Flywheels; Thermal Stresses in Cylinders; Exact Stresses in Curved Beams; Curved Beam Formula; Circular Plates; Thin Shells of Revolution; Special Cases of Shells of Revolution; Pressure Vessels and Piping; Filament-Wound Pressure Vessels; Buckling of Cylindrical and Spherical Shells; Problems; ; Finite Element Analysis in Design ; Introduction; Bar Element; Formulation of the Finite Element Method; Beam Element; Two-Dimensional Elements; Triangular Element; Plane Stress Case Studies; Problems; ; Case Studies in Machine Design ; Introduction; Floor Crane with Electric Winch; High-Speed Cutter; Problems; Appendices ; Answers to Selected Problems ; <B&gt … (more)
- Edition:
- Second edition SI version
- Publisher Details:
- London : Taylor & Francis
- Publication Date:
- 2016
- Extent:
- 1 online resource, illustrations (black and white)
- Subjects:
- 621.815
Machine parts -- Design and construction
Machine design - Languages:
- English
- ISBNs:
- 9781498735407
9781498735377
9781498735391 - Related ISBNs:
- 9781498735360
- Notes:
- Note: Includes bibliographical references and index.
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- Legal Deposit; Only available on premises controlled by the deposit library and to one user at any one time; The Legal Deposit Libraries (Non-Print Works) Regulations (UK).
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- Restricted: Printing from this resource is governed by The Legal Deposit Libraries (Non-Print Works) Regulations (UK) and UK copyright law currently in force.
- View Content:
- Available online (eLD content is only available in our Reading Rooms) ↗
- Physical Locations:
- British Library HMNTS - ELD.DS.216305
- Ingest File:
- 02_263.xml