An Overview of Engineering Mechanics required to comprehend ASME Piping and Pressure Vessel Code
Why Do You Enroll?
Unlock the secrets of ASME Piping and Pressure Vessel Code with our comprehensive course, "An Overview of Engineering Mechanics." This essential training provides a solid foundation in the fundamental principles of engineering mechanics, crucial for understanding and applying the ASME Code.
Invest in your career and ensure compliance with ASME standards. Enroll now and master the engineering mechanics essential for safe and reliable piping and pressure vessel design.
The participants will learn the advanced solid mechanics concepts to comprehend International codes (ASME B31.3, ASME BPVC, etc) in a better way.
1. How elementary and advanced topics of Solid mechanics are applied in the development of Piping and Pressure vessel codes and standards.
2. Theoretical background behind design code requirements which helps an engineer understand the strengths, weaknesses, and applicability of the code requirements.
3. An insight into the newly introduced codes.
4. Bridging the gap between theoretical knowledge and code requirements.
5. University students who want to take up career in piping engineering or static equipment engineering and wants to learn about the most widely used Industrial standard.
6. Experienced engineers who want to understand the background of code rules and requirements
...Key Topics Covered
This module of the course covers the following topics
Stress Concept
Failure Theory
Euler-Bernoulli and Timoshenko Beam theories.
Fatigue concept
Theory of Plates and Shells.
Theory of Thick Cylinders
Concepts of SIF
Course Details
This course will cover basic and advanced topics from Solid Mechanics required to provide a robust understanding of the background theory behind technical requirements of Piping and Pressure Vessel codes and standards. A refresher course on core and advanced topics of Solid mechanics required to understand technical background of Piping and Pressure Vessel codes and standards.
...Course Content
1. Concepts of Stress- Definition, Principal Stress, Octahedral Shear Stress, Deviatoric and Hydrostatic components.
Concepts of Stress- Definition, Principal Stress, Octahedral Shear Stress, Deviatoric and Hydrostatic components.
2. Fatigue-stress and strain based approaches, overview of fracture mechanics concepts, rainflow counting, cyclic stress-strain curves, Concept of Ratcheting/alternate plasticity
Fatigue-stress and strain based approaches, overview of fracture mechanics concepts, rainflow counting, cyclic stress-strain curves, Concept of Ratcheting/alternate plasticity
3. Theory of plates-basic assumptions, Mindlin and Kirchoff models, circular plates.
Theory of plates-basic assumptions, Mindlin and Kirchoff models, circular plates.