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Fundamentals of Machine Component Design
- 1st Edition - September 25, 2023
- Author: Wael A. Altabey
- Language: English
- Paperback ISBN:9 7 8 - 0 - 4 4 3 - 2 1 4 4 9 - 3
- eBook ISBN:9 7 8 - 0 - 4 4 3 - 2 1 4 5 0 - 9
Fundamentals of Machine Component Design bridges theory and practice to provide readers with a thorough understanding of best practices for machine component design and applic… Read more
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Request a sales quoteFundamentals of Machine Component Design bridges theory and practice to provide readers with a thorough understanding of best practices for machine component design and application. Load and stress analysis, fatigue, fracture, and other mechanical behaviors that can result in the failure of a machine component are discussed in the early chapters before the book moves on to cover different connections (welded and bolted) prevalent in machine components, and then individual components such as gears, shafts, bearings, springs, pressure vessels, brakes, clutches, keys and couplings, and more. The book ends with chapters outlining different design methods as well as design problems for readers to practice with. Solutions are also provided.
- Covers the design of shafts, power screws, bolts, welded connections, springs, and pressure vessels, as well as transmitted power elements such as belts, chains, gears, and wire ropes
- Outlines finite element methods and other techniques that can be used for effectively designing machine components
- Discusses contact and sliding bearings, keys and couplings, gears (helical, spur, bevel, and worm), and more
- Includes solved problems to help readers refine their skills
Advanced undergraduate and graduate-level engineering students; academic researchers; Professionals in a broad array of engineering disciplines working with machine design
- Cover image
- Title page
- Table of Contents
- Copyright
- About the author
- Preface
- Acknowledgments
- Chapter 1: Introduction
- Abstract
- 1.1: Codes and Standards
- 1.2: Basic procedures of machine design
- 1.3: Design considerations
- 1.4: Stress and Strength
- Bibliography
- Chapter 2: Load and stress analysis
- Abstract
- 2.1: Load analysis
- 2.2: Stress analysis
- 2.3: Load and stress analysis problems
- Bibliography
- Chapter 3: Theories of failure
- Abstract
- 3.1: Failure theories
- 3.2: Theories of failure problems
- Bibliography
- Chapter 4: Fatigue failure resulting from variable loading
- Abstract
- 4.1: Introduction
- 4.2: Examples of fatigue failures
- 4.3: Fatigue life methods
- 4.4: Endurance limit modifying factors
- 4.5: Characterizing fluctuating stresses
- 4.6: Fatigue failure criteria for fluctuating stress
- 4.7: Fatigue failure resulting from variable loading problems
- Bibliography
- Chapter 5: Deflection and stiffness
- Abstract
- 5.1: Deflection due to bending
- 5.2: Beam deflection methods
- 5.3: Compression column (buckling)
- 5.4: Deflection and stiffness problems
- Bibliography
- Chapter 6: Bolted connections
- Abstract
- 6.1: Introduction
- 6.2: A single bolted connection or a group of N bolts loaded centrally
- 6.3: A group of bolts loaded non-centrally
- 6.4: Bolted connections problems
- Bibliography
- Chapter 7: Welded connections
- Abstract
- 7.1: Introduction
- 7.2: Types of welded joint
- 7.3: Welding symbols
- 7.4: Stress analysis
- 7.5: Welded connections problems
- Bibliography
- Chapter 8: Mechanical power screw
- Abstract
- 8.1: Introduction
- 8.2: Advantages of power screws
- 8.3: Thread types and thread specifications
- 8.4: Design of power screw
- 8.5: The stresses in power screw
- 8.6: Mechanical power screw problems
- Bibliography
- Chapter 9: Belt and chain drives
- Abstract
- 9.1: Belt drive
- 9.2: Roller chain drive
- 9.3: Belt and chain drive problems
- Bibliography
- Chapter 10: Wire rope
- Abstract
- 10.1: Introduction
- 10.2: Wire rope specifications
- 10.3: Wire rope materials
- 10.4: Wire rope design
- 10.5: Wire rope design problems
- Bibliography
- Chapter 11: Gears
- Abstract
- 11.1: Introduction
- 11.2: Types of gears
- 11.3: Gear terminology
- 11.4: Gear geometry
- 11.5: Spur gear
- 11.6: Helical gears
- 11.7: Bevel gears
- 11.8: Worm gears
- 11.9: Spur gear tooth design using AGMA methodology
- 11.10: Gear problems
- Bibliography
- Chapter 12: Shafts
- Abstract
- 12.1: Introduction
- 12.2: Types of shafts
- 12.3: Standard sizes of shafts
- 12.4: Material for shafts
- 12.5: Shaft layout
- 12.6: Design considerations for shaft
- 12.7: Shaft problems
- Bibliography
- Chapter 13: Contact bearings
- Abstract
- 13.1: Introduction
- 13.2: Types of bearings
- 13.3: Static load
- 13.4: Bearing standard dimensions
- 13.5: Bearing selection
- 13.6: Contact bearing problems
- Bibliography
- Chapter 14: Sliding bearings
- Abstract
- 14.1: Introduction
- 14.2: Viscosity
- 14.3: Sliding bearing problems
- Bibliography
- Chapter 15: Mechanical springs
- Abstract
- 15.1: Introduction
- 15.2: Stresses in helical springs
- 15.3: The curvature effect
- 15.4: Deflection of helical springs
- 15.5: Spring materials
- 15.6: Spring design equation
- 15.7: Spring work done
- 15.8: Spring connections
- 15.9: Critical frequency of helical springs
- 15.10: Fatigue loading of helical compression spring
- 15.11: Extension springs
- 15.12: Helical torsion springs
- 15.13: Mechanical spring problems
- Bibliography
- Chapter 16: Pressure vessels
- Abstract
- 16.1: Introduction
- 16.2: Stress analysis in pressurized cylinders
- 16.3: Pressure vessel problems
- Bibliography
- Chapter 17: Clutches
- Abstract
- 17.1: Introduction
- 17.2: Clutch starting analysis
- 17.3: Axial clutch types
- 17.4: Disk clutch type
- 17.5: Cone clutch type
- 17.6: Clutch problems
- Bibliography
- Chapter 18: Brakes
- Abstract
- 18.1: Introduction
- 18.2: Band brake
- 18.3: External shoe drum brake
- 18.4: Internal shoe drum brake (the automotive brake)
- 18.5: Brake problems
- Bibliography
- Chapter 19: Keys and couplings
- Abstract
- 19.1: Shaft keys
- 19.2: Shaft couplings
- 19.3: Keys and couplings problems
- Bibliography
- Chapter 20: Design by numerical method
- Abstract
- 20.1: Finite element method
- 20.2: Elasticity equations
- 20.3: General steps of the finite element method
- 20.4: Finite element types
- 20.5: Derivation of spring element equations using direct stiffness method
- 20.6: Bar element formulation using direct stiffness method
- 20.7: Thermal analysis
- 20.8: Finite element method problems
- 20.9: Results
- Bibliography
- Chapter 21: The optimum design methods
- Abstract
- 21.1: Introduction
- 21.2: Definitions
- 21.3: Types of optimization
- 21.4: Graphical method
- 21.5: Analytical method
- 21.6: Numerical method
- 21.7: The optimum design methods problems
- Bibliography
- Appendix: Complete design problems
- Index
- No. of pages: 700
- Language: English
- Edition: 1
- Published: September 25, 2023
- Imprint: Elsevier
- Paperback ISBN: 9780443214493
- eBook ISBN: 9780443214509
WA
Wael A. Altabey
Prof. Wael A. Altabey is an Associate Professor at Southeast University, Nanjing, China. He was awarded a post-doctoral research fellowship certificate in AI-based schemes for SHM, and damage detection of composite structures by Southeast University in 2018. Before that, he was an Associate Professor at the Mechanical Engineering Department, Faculty of Engineering, Alexandria University, Alexandria, Egypt. Prof. Wael A. Altabey has studied machine design and optimum design for more than 10 years in a variety of class sizes in different universities with remarkable student diversity. He discussed machine design and optimum design methods and theories in several publications published by high impact factors journals.
Affiliations and expertise
Associate Professor, Southeast University, Nanjing, ChinaRead Fundamentals of Machine Component Design on ScienceDirect