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Book Cover
E-book
Author Dixit, Uday S.

Title Autofrettage Processes : Technology and Modelling
Published Boca Raton : CRC Press LLC, 2019

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Description 1 online resource (277 pages)
Contents Cover; Half Title; Title Page; Copyright Page; Dedication Page; Contents; Preface; Authors; 1: Introduction to Autofrettage; 1.1 What Is Autofrettage?; 1.2 A Brief History of the Autofrettage Process; 1.3 Application of the Autofrettage Process; 1.4 Classification of Autofrettage Processes; 1.4.1 Hydraulic Autofrettage; 1.4.2 Swage Autofrettage; 1.4.3 Explosive Autofrettage; 1.4.4 Thermal Autofrettage; 1.4.5 Rotational Autofrettage; 1.5 Conclusion; References; 2: A Review on Plasticity and the Finite Element Method; 2.1 Introduction; 2.2 Index Notation; 2.3 Measures of Strain and Stress
2.4 Equations of Motion2.5 Strain-Displacement Relations; 2.6 Incremental Strain and Strain Rate Measures of Plastic Deformation; 2.7 Yield Criterion; 2.7.1 Tresca Yield Criterion; 2.7.2 Von Mises Yield Criterion; 2.8 Criterion for Subsequent Yielding; 2.9 Stress-Incremental Strain and Stress-Strain Rate Relation During Plastic Deformation; 2.10 Introduction to the Finite Element Method (FEM); 2.10.1 Preprocessing; 2.10.2 Developing Elemental Equations; 2.10.2.1 Direct Stiffness Method; 2.10.2.2 Weighted Residual Method; 2.10.3 Assembling the Elemental Equations
2.10.4 Applying Boundary Conditions and Solving the System of Equations2.10.5 Post-Processing; 2.11 An Example of Hydraulic Autofrettage of a Thick Cylinder; 2.12 Conclusion; References; 3: Hydraulic Autofrettage; 3.1 Introduction; 3.2 A Typical Hydraulic Autofrettage Process; 3.3 Aspects in Modeling Hydraulic Autofrettage; 3.4 Elastic Analysis of an Internally Pressurized Thick-Walled Cylinder; 3.5 Closed-Form Model of Hydraulically Autofrettaged Cylinder Based on the Tresca Yield Criterion; 3.5.1 Stress Distribution after Loading; 3.5.2 Residual Stress Distribution after Unloading
3.6 Closed-Form Model of Hydraulically Autofrettaged Cylinder Based on von Mises Yield Criterion3.6.1 Cylinder with Open Ends or Disc with Plane-Stress Condition; 3.6.1.1 Stress Distribution after Loading; 3.6.1.2 Residual Stress Distribution after Unloading; 3.6.2 Cylinder with Constrained Ends/Plane-Strain Condition; 3.6.2.1 Stress Distribution after Loading; 3.6.2.2 Residual Stress Distribution after Unloading; 3.7 Elastic Analysis of an Internally Pressurized Thick-Walled Sphere; 3.8 Closed-Form Model of a Hydraulically Autofrettaged Sphere; 3.8.1 Stress Distribution after Loading
3.8.2 Residual Stress Distribution after Unloading3.9 Results and Discussion; 3.10 Conclusion; References; 4: Swage and Explosive Autofrettage; 4.1 Introduction; 4.2 A Typical Swage Autofrettage Process; 4.3 Issues in Modeling the Swage Autofrettage Process; 4.3.1 Effect of Mandrel Geometry; 4.3.2 Effect of the Mandrel Material Behavior; 4.3.3 Effect of Friction between Mandrel and Cylinder; 4.3.4 Effect of Number of Passes; 4.4 Closed-Form Model of Swage Autofrettage; 4.4.1 Elastic Analysis; 4.4.2 Elasto-Plastic Analysis; 4.5 Typical Results in Swage Autofrettage; 4.6 Explosive Autofrettage
Summary Autofrettage Processes: Technology and Modeling deals with the technology and modeling of autofrettage processes, explaining the subject in a lucid manner. It highlights how the theory of plasticity and finite element modeling are applied in the modeling of autofrettage processes. Aimed at senior students of mechanical, production, automobile, and chemical engineering, it has the potential to directly benefit practicing engineers and industrials, owing to the inclusion of topics like thermal autofrettage. Key Features: Provides a general introduction to autofrettage Covers the application of theory of plasticity and finite element modeling of autofrettage processes Offers exposure to newer autofrettage processes that to date have not been implemented in industries, along with useful practical data
Notes 4.7 Conclusion
Dr. Uday Shanker Dixit received B.E. degree in Mechanical Engineering from erstwhile University of Roorkee (now Indian Institute of Technology Roorkee) in 1987, M.Tech. degree in Mechanical Engineering from Indian Institute of Technology Kanpur in 1993, and Ph.D. in Mechanical Engineering from IIT Kanpur in 1998. He has worked in two industries-- HMT, Pinjore and INDOMAG Steel Technology, New Delhi, where his main responsibility was designing various machines. Dr. Dixit joined the Department of Mechanical Engineering, Indian Institute of Technology Guwahati, in 1998, where he is currently a professor. He was also the Officiating Director of Central Institute of Technology, Kokrajhar from February 2014 to May 2015. Dr. Dixit is actively engaged in research in various areas of design and manufacturing since last 25 years. He has authored/co-authored 109 journal papers, 104 conference papers, 26 book chapters and 6 books in mechanical engineering. He has also co-edited 7 books related to manufacturing. He has guest-edited 11 special issues of journals. Presently he is an Associate Editor of the Journal of Institution of Engineers (India), Series C and the Regional Editor (Asia) of International Journal of Mechatronics and Manufacturing Systems. He has guided 11 doctoral and 43 masters' students. Dr. Dixit has investigated a number of sponsored projects and developed several courses. Presently, he is the Vice-President of AIMTDR conference. Dr. Seikh Mustafa Kamal obtained a bachelor's degree in Mechanical Engineering from Jorhat Engineering College, Jorhat, Assam, India in 2009 and a PhD in Mechanical Engineering from Indian Institute of Technology Guwahati in 2016. He has served as Assistant Professor of Mechanical Engineering at NITS Mirza, Guwahati for a period of about three years (2009−2012) prior to joining the direct PhD programme at Indian Institute of Technology Guwahati. Dr. Kamal joined the Department of Mechanical Engineering, Tezpur University, Assam, India in 2016, where he is currently an Assistant Professor. He is an active researcher in the area of autofrettage, plasticity and stress analysis. During his PhD, he developed a new thermal autofrettage method for strengthening thick-walled pressure vessels under the supervision of Prof. U. S. Dixit. His recent research interest is in exploring rotational autofrettage. He has published 6 journal papers, 7 conference papers and 2 book chapters on the area of autofrettage. He has edited one conference proceedings (Proceedings of the National Conference on Sustainable Mechanical Engineering: Today and Beyond, 25−26 March, 2017, Tezpur University, India) and guided 2 Masters' students. Mr. Rajkumar Shufen received his bachelor's degree in Production engineering from Birla Institute of Technology and Mesra, Ranchi in 2011 and Master's degree in Engineering Design from Birla Institute of Technology and Science in 2015. He has worked in an US based firm Fluor Daniel Corporation for two years in Gurgaon, India as an Associate Piping Design Engineer. He has earned significant industrial experience in plant design, piping layouts, pump piping and pressure vessels. He is currently pursuing Ph.D. in Mechanical Engineering from Indian Institute of Technology, Guwahati. Since joining his Ph.D. he has published three research journal papers. His research areas include computational solid mechanics, plasticity, pressure vessels and material science
Print version record
Subject Metal-work.
Metals -- Cold working.
Deformations (Mechanics)
Finite element method.
metalworking.
strain hardening.
deformation.
cold-working (metal-forming process)
SCIENCE -- Mechanics -- General.
TECHNOLOGY -- Material Science.
TECHNOLOGY -- Metallurgy.
Deformations (Mechanics)
Finite element method
Metal-work
Metals -- Cold working
Form Electronic book
Author Kamal, Seikh Mustafa
Shufen, Rajkumar
ISBN 9780429757990
0429757999
9780429425431
0429425430
9780429757976
0429757972
9780429757983
0429757980