Design by Analysis for Pressure Vessels and Heat Exchangers according to ASME Codes

This course focuses on the application of design-by-analysis methodologies in alignment with ASME codes, which are widely recognized and adopted in the industry. Participants will gain a deep understanding of the design principles, material selection, loadings, and various analysis techniques required to ensure structural integrity and optimize the performance of pressure vessels and heat exchangers.

Course Highlights

The course is a comprehensive program designed to equip engineers and professionals with the knowledge and skills necessary to perform advanced design and analysis of pressure vessels and heat exchangers.

Through a combination of theoretical lectures, practical examples, and case studies, participants will learn how to employ finite element analysis (FEA) for stress analysis, fatigue evaluation, buckling and stability analysis, creep analysis, and more. The course also covers topics such as non-linear analysis, residual stress analysis, and the integration of design by analysis with other design approaches.

By the end of the course, participants will have a strong foundation in design by analysis, enabling them to confidently apply these methodologies to tackle real-world challenges in pressure vessel and heat exchanger design. Whether you are an engineer, designer, or professional involved in the design and analysis of pressure vessels and heat exchangers, this course will enhance your skills and expertise, ensuring compliance with ASME codes and industry best practices.

Course Objective

The course is a comprehensive program designed to equip engineers and professionals with the knowledge and skills necessary to perform advanced design and analysis of pressure vessels and heat exchangers.

Through a combination of theoretical lectures, practical examples, and case studies, participants will learn how to employ finite element analysis (FEA) for stress analysis, fatigue evaluation, buckling and stability analysis, creep analysis, and more. The course also covers topics such as non-linear analysis, residual stress analysis, and the integration of design by analysis with other design approaches.

By the end of the course, participants will have a strong foundation in design by analysis, enabling them to confidently apply these methodologies to tackle real-world challenges in the pressure vessel and heat exchanger design. Whether you are an engineer, designer, or professional involved in the design and analysis of pressure vessels and heat exchangers, this course will enhance your skills and expertise, ensuring compliance with ASME codes and industry best practices.

Course Prerequisite

  • Engineering Background: Participants should have a foundational knowledge of engineering principles, including mechanics, materials, and structural analysis.
  • Basic Understanding of Pressure Vessels and Heat Exchangers: Familiarity with the basic concepts and terminology related to pressure vessels and heat exchangers will be beneficial.
  • Knowledge of ASME Codes: It is recommended that participants have a basic understanding of the ASME Boiler and Pressure Vessel Code (BPVC), particularly sections related to pressure vessels and heat exchangers.
  • Proficiency in Engineering Mathematics: A good understanding of mathematics, including calculus and linear algebra, will be essential for comprehending the analytical aspects of design by analysis.
  • Finite Element Analysis (FEA) Knowledge: While not mandatory, prior exposure to FEA concepts and techniques will facilitate understanding and application of FEA methods in the course.
  • Computer Skills: Participants should have basic computer skills and familiarity with engineering software packages commonly used for structural analysis, such as FEA software (e.g., ANSYS, Abaqus) and CAD software (e.g., SolidWorks, AutoCAD).

About Instructor

Shirsh Technosolutions .

Shirsh's team is a collective of amazing people with domain expertise striving to help you build delightful products. We mold your product concept into practical reality through our comprehensive computer-aided engineering solutions which will lead to securing initial product quality, a decrease in product development time, and reduced costs. With the increase in the number of simulations, the need for producing physical prototypes will significantly decrease.

9 Courses

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Course Includes

  • 13 Modules
  • 1 Topic