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"Pressure Vessels: Design and Practice" by Somnath Chattopadhyay (Repost)

Posted By: exLib
"Pressure Vessels: Design and Practice" by Somnath Chattopadhyay (Repost)

"Pressure Vessels: Design and Practice" by Somnath Chattopadhyay
Mechanical Engineering Series, 25
СRС Prеss, Tауlоr & Frаnсis | 2005 | ISBN: 0849313694 9780849313691 | 194 pages | PDF | 5 MB

This book provides a comprehensive, in-depth guide on everything engineers need to know. With emphasis on the requirements of the ASME this consummate work examines the design of pressure vessel components with explanations that clearly emphasize the inherent design principles and philosophy.

With equations and procedures for designing the main parts of pressure vessels, this volume is a convenient resource and reference. The book covers the basic theories and principles behind the stress limiting conditions in the codes. It is also a practical guide for designing and building pressure vessels of all types.

Not just a 'cookbook,' this volume allows you to trace the origin of the design equations used in the construction codes, offering a valuable, physical insight into the design process.

Chapters thoroughly cover stresses in shells, covers and flanges, vessel supports, and includes reviews of fatigue and fracture mechanics, structural stability, and limit analysis.

Contents
Chapter 1 Overview of pressure vessels
1.1 Introduction
1.2 Development of pressure vessel construction codes
References
Chapter 2 Pressure vessel design philosophy
2.1 General overview
2.2 Structural and material considerations
2.3 Factor of safety
2.4 Design by rule
2.5 Design by analysis
References
Chapter 3 Structural design criteria
3.1 Modes of failure
3.2 Theories of failure
3.3 Theories of failure used in ASME Boiler and Pressure Vessel Code
3.4 Allowable stress limits in the ASME Boiler and Pressure Vessel Code
3.5 Service limits
3.6 Design for cyclic loading
3.7 Protection against fracture
References
Problems
Chapter 4 Stress categories and stress limits
4.1 Introduction
4.2 Stress intensity
4.3 Categorization of stresses
4.3.1 Primary stress
4.3.2 Secondary stress
4.3.3 Peak stress
4.4 Stress limits
4.5 Special stress limits
4.6 Practical aspects of stress categorization
4.7 Shape factor considerations
References
Problems
Chapter 5 Design of cylindrical shells
5.1 Introduction
5.2 Thin-shell equations
5.3 Thick-shell equations
5.4 Approximate equations
5.5 Buckling of cylindrical shells
5.6 Discontinuity stresses in pressure vessels
References
Problems
Chapter 6 Design of heads and covers
6.1 Introduction
6.2 Hemispherical heads under internal pressure
6.3 ASME equation for hemispherical heads
6.4 Example problem 1
6.4.1 Thin-shell theory
6.4.2 "Exact" theory
6.4.3 ASME equation (assuming E ¼ 1)
6.5 ASME design equation for ellipsoidal heads
6.6 ASME equation for torispherical heads
6.7 Example problem 2
6.7.1 Solution for ASME head using Eq. (6.15)
6.8 ASME design equations for conical heads
6.9 ASME design equations for toriconical heads
6.10 Flat heads and covers
6.10.1 Case 1
6.10.2 Case 2
6.11 ASME equation for unstayed flat heads and covers
6.12 Example problem 3
6.12.1 Considering simply supported edges
6.12.2 Considering clamped edges
6.12.3 Considering unstayed plates and covers
References
Chapter 7 Design of nozzles and openings
7.1 Introduction
7.2 Stress concentration about a circular hole
7.3 Cylindrical shell with a circular hole under internal pressure
7.4 Spherical shell with a circular hole under internal pressure
7.5 Reinforcement of openings
7.5.1 Reinforcement example problem
7.6 Nozzles in pressure vessels
References
Chapter 8 Fatigue assessment of pressure vessels
8.1 Introduction
8.2 Exemption from fatigue analysis
8.3 S–N curves
8.4 Local strain approach to fatigue
8.5 Design fatigue curves
8.6 Cumulative damage
8.7 Cycle counting
8.8 Fatigue evaluation procedure
8.9 Example of fatigue evaluation
References
Problems
Chapter 9 Bolted flange connections
9.1 Introduction
9.2 Gasket joint behavior
9.3 Design of bolts
9.4 Examples
9.4.1 Problem 1
9.4.2 Problem 2
9.5 Closure
References
Problems
Chapter 10 Design of vessel supports
10.1 Introduction
10.2 Lug support
10.3 Support skirts
10.3.1 Example problem
10.3.2 Solution
10.4 Saddle supports
References
Chapter 11 Simplified inelastic methods in pressure vessel design
11.1 Introduction
11.2 Elastic analysis incorporating modified Poisson’s ratio
11.3 Elastic analysis to address plastic strain intensification
11.4 Conclusion
References
Chapter 12 Case studies
12.1 Introduction
12.2 Sizing of a pressure vessel
12.2.1 Example problem
12.2.2 Solution
12.3 Nozzle reinforcement assessment
12.3.1 Vessel and nozzle thickness calculations
12.3.2 Reinforcement calculations
12.4 Fatigue evaluation using elastic analysis
12.5 Fatigue evaluation using the simplified inelastic analysis
method
12.6 Structural evaluation of a reactor vessel support
References
Appendix A Review of solid mechanics
A.1 Introduction
A.2 Concept of stress
A.3 Equations of equilibrium in a cylindrical system
A.4 Principal stresses
A.5 Strain
A.6 Stress-strain relations
A.7 Elastic plane problems
A.7.1 Plane strain
A.7.2 Plane stress
A.7.3 Stress function formulation
A.8 Plasticity
Appendix B Review of fatigue and fracture mechanics
B.1 S–N curves
B.2 Cumulative fatigue damage
B.3 Basic fracture mechanics
B.4 Example
B.4.1 Solution
Appendix C Limit analysis
C.1 Shape factor
C.2 Collapse phenomena and limit theorems
with TOC BookMarkLinks