Presenting time-tested standards as well as validated emerging knowledge on threaded fasteners and bolted joints, this updated edition covers how to design, select parts and materials, control assembly processes, predict behavior, and solve on-the-job problems.
This handbook examines key issues affecting bolting in the automotive, pressure vessel, petrochemical, aerospace, energy, and structural steel industries. The editors have successfully created a useful rather than scholarly handbook with chapters written in a straightforward, how-to manner. Theory is discussed only when necessary and the handbooks logical organization and thorough index enhance its usefulness. Handbook of Bolts and Bolted Joints, Second Edition includes updated chapters, solved numerical examples, and case studies.
This new edition is an essential handbook for professionals, researchers, and students in all fields in which threaded joints are used, including automotive, aerospace, structural, chemical, and naval and ocean engineering, as well as agricultural equipment, wind turbines, and medical devices.
Presenting time-tested standards, as well as validated emerging knowledge on threaded fasteners and bolted joints, this updated edition covers how to design, select parts and materials, control assembly processes, predict behavior, and solve on-the-job problems.
PART I: Material Properties and Selection
1. Fastener Materials
2.
Joining with Aluminum Alloy Bolts and Nuts
3. Titanium Screw Joint Systems
PART II: Processing of Fasteners
4. Fastener Manufacturing
5. Fastener
Coatings
6. Thread Lubricants
7. Tribology of Threaded Joints: Sustainable
Lubricants PART III: Threaded Fastners
8. Computing the Strength of a
Fastener
9. Computing the Stiffness of a Fastener
10. Computing Joint
Stiffness
11. Washers: A Guide to Their Function and Selection
12.
Vibration-Resistant Fasteners
13. Aerospace Bolts
14. Thread Forming,
Self-Tapping, and Thermoplastic Screws PART IV: Design and Analysis of Bolted
Joints
15. VDI Joint Design Procedures
16. Design Guidelines for Automotive
Bolted Joints
17. Design of Gasketed Joints 18.ASME Boiler and Pressure
Vessel Code Design Rules for Bolted Flanges 19.Fastener Selection for
Non-Metallic Automotive Joints
20. Design of Joints Loaded in Shear
21.
Design Rules for Structural Steel Bolting
22. Quality Inspection of
Automotive Joints PART V: Assembly of Bolted Joints
23. Behavior of a Bolted
Joint During Assembly
24. Tightening Groups of Fasteners in a Structure and
the Resulting Elastic Interactionl
25. Hydraulic Stud Tensioning
26.
Torque-Control of Bolt Tightening
27. Torque-Angle Control of Bolt Tightening
28.Torque-to-Yield Control Process of Bolt Tightening
29. Stretch Control
30.
Use of Ultrasonics in Bolted Joints
31. Control with Direct Tension
Indicators
32. Selecting Preload for an Existing Joint PART VI: The Joint in
Service
33. Clamp Load Decay in Multi-Material Joints Due to Cyclic Heating
and Cooling
34. Joint Diagrams
35. Loss of Clamp Load in Post-Yielded Joint
Systems Subjected to Axial Service Loading
36. Fatigue Performance of
Ultra-High Strength Metric Bolts
37. Fatigue Testing of A286 Steel Bolts
38.
Improved Criterion for Cumulative Fatigue Damage of Preloaded Steel Bolts
39.
The Susceptibility of Fasteners to Hydrogen Embrittlement and Stress
Corrosion Cracking
40. Vibration- and Shock-Induced Loosening
41. Vibration
Loosening Analysis and Simulation of Preloaded Threaded Fasteners PART VII:
Testing and Inspection of Bolts and Joints
42. Field Testing of Structural
Bolts and Installation Tools Using a Bolt Tension Calibrator
43.
TorqueTension Audits
44. Statistical Design and Analysis of Multivariable
Experiments
45. Case Study: Rupture of a Wind Turbine Composite Blade-to-Hub
Bolted Joint
Sayed A. Nassar is a fellow of ASME, the John F. Dodge Chair of Engineering, Distinguished Professor of Mechanical Engineering, and founding director of the Fastening and Joining Research Institute (FAJRI), Oakland University (OU), Rochester, Michigan. He is also the founding director of the OU site of funded NSF IUCRC Center for Composite and Hybrid Material Interfacing (CHMI) which has two more sites at Georgia Institute of Technology and the University of TennesseeKnoxville. At OU, Dr. Nassar teaches graduate and undergraduate courses in design, solid mechanics, and material joining; his current research is predominantly in the area of material joining, where he supervised more than 35 PhD and MS theses and published more than 300 peerreviewed papers on the subject. Dr. Nassar holds seven US and International patents and is the founding president of University Research and Engineering Consultants (UREC LLC), Northville, Michigan. He is currently the chair of Fastening and Joining Committee, Design Division of ASME. Dr. Nassar received his MS and Ph.D. in Aerospace Engineering (Structural Mechanics) from the University of Cincinnati, Cincinnati, Ohio.
John H. Bickford is a private consultant, Middletown, Connecticut. He was formerly vicepresident of Raymond Engineering, Inc., and manager of its Bolting Products Division in Middletown, Connecticut.
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