Fatigue Failure in Different Fields of Engineering
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Course Summary
This course explores the concept of fatigue failure in various fields of engineering, including aerospace, civil, mechanical, and materials engineering. Students will learn about the causes of fatigue failure and how to prevent it through different design strategies and materials selection.Key Learning Points
- Understand the concept of fatigue failure and its impact on different engineering fields
- Learn the causes and mechanisms of fatigue failure
- Explore different design strategies and materials selection to prevent fatigue failure
Job Positions & Salaries of people who have taken this course might have
- USA: $70,000 - $100,000
- India: ₹400,000 - ₹1,000,000
- Spain: €25,000 - €50,000
- USA: $70,000 - $100,000
- India: ₹400,000 - ₹1,000,000
- Spain: €25,000 - €50,000
- USA: $80,000 - $130,000
- India: ₹600,000 - ₹2,000,000
- Spain: €30,000 - €60,000
- USA: $70,000 - $100,000
- India: ₹400,000 - ₹1,000,000
- Spain: €25,000 - €50,000
- USA: $80,000 - $130,000
- India: ₹600,000 - ₹2,000,000
- Spain: €30,000 - €60,000
- USA: $70,000 - $110,000
- India: ₹500,000 - ₹1,500,000
- Spain: €25,000 - €50,000
Related Topics for further study
Learning Outcomes
- Ability to identify and analyze fatigue failure in mechanical, civil, aerospace, and materials engineering
- Knowledge of different design strategies and materials selection to prevent fatigue failure
- Understanding of the causes and mechanisms of fatigue failure
Prerequisites or good to have knowledge before taking this course
- Basic knowledge of engineering principles and materials science
- Familiarity with mechanical design and testing
Course Difficulty Level
IntermediateCourse Format
- Online
- Self-paced
- Video lectures
Similar Courses
- Introduction to Materials Science and Engineering
- Structural Materials: Selection and Properties
- Aerospace Materials and Manufacturing
Related Education Paths
- Mechanical Engineering Certification
- Aerospace Engineering Certification
- Materials Science Certification
Notable People in This Field
- Dr. Fatigue
- Dr. Materials
Related Books
Description
In recent years, owing to global competition and greater need of customers for safety, durability, and reliability of products, there has been a considerable tendency to improve quality in various industries. In this regard, fatigue is one of the major reasons of industrial failures, which is sometimes caused by lack of awareness or attention by the designer and other parts of industry like R&D. The aim of this course is to introduce MSc graduates, Ph.D. students, and engineers working in industry with a short review of the basics of fatigue in different fields of engineering. To this end, it is attempted to express the general concept of the phenomenon using unconscious reactions of the human body to daily works and then to illustrate other aspects through simple examples. The topics cover common challenges that engineers should consider to study the causes of component failure.
Outline
- Introduction
- Intro video
- Introduction
- Different types of failure and importance of fatigue failure
- Report of some huge losses of fatigue failures
- Macro aspect of material fatigue by human body language
- Stages of fatigue failure from view point of medical science
- Various ways to delay the fatigue feeling
- Introduction to Fatigue Failures in Different Fields of Engineering
- Different types of failure and importance of fatigue failure
- Some huge losses of fatigue failures in the world
- Macro aspect of material fatigue by human body language
- Different stages of fatigue failures
- Various methods for delaying time of fatigue failure
- Test #1
- Real examples of fatigue failure in various industries
- Real examples of fatigue failure in various industries, including Mechanical engineering
- Automotive engineering
- Civil engineering
- Computer, Electrical, and Textile engineering
- Aerospace and Transportation engineering
- Petrochemical engineering
- Sea, Energy, and Material engineering
- Biomedical engineering
- Real examples in various fields of engineering
- Automotive engineering
- Civil engineering
- Computer, Electrical, and Textile engineering
- Aerospace and Transportation engineering
- Petrochemical engineering
- Sea, Energy, and Material engineering
- Biomedical engineering
- Test #2
- Fatigue design criteria and design flowchart
- Fatigue design flowchart
- Design of steering knuckle as a super-critical component of automotive (steps 1-5)
- Design of steering knuckle as a super-critical component of automotive (steps 6-10)
- Strategies in fatigue design
- Fatigue design criteria
- Crack inspection and sizing in service
- Fatigue testing machine
- Fatigue test specimen preparation and important points in fatigue experiment
- Fatigue design flowchart
- Design of steering knuckle as a super-critical component of automotive
- Strategies in fatigue design
- Fatigue design criteria
- Crack inspection and sizing in service
- Fatigue testing machine
- Fatigue test specimen preparation and important points in fatigue experiment
- Test #3
- Test #4
- Classification of fatigue loads and life estimation
- Different types of fatigue loads
- Multiaxial stress-strain field
- Features of S-N diagram and high-cycle fatigue life approach
- Effect of mean stress on HCF life
- Linear damage accumulation rule
- Various cycle counting techniques and tutorial of J-rain software
- Different types of fatigue loads
- Multiaxial stress-strain field
- Features of S-N diagram and high-cycle fatigue life approach
- Effect of mean stress on HCF life
- Linear damage accumulation rule
- Various cycle counting techniques and tutorial of J-rain software
- Test #5
- Solve fatigue problems using the formula and FE simulation
- Solve high-cycle fatigue problems using formula (Part 1)
- Solve high-cycle fatigue problems using formula (Part 2)
- Tutorial of ANSYS Workbench (geometric modeling)
- Tutorial of ANSYS Workbench (finite element simulation)
- Tutorial of ANSYS Workbench (static analysis)
- Tutorial of ANSYS Workbench (fatigue analysis)
- Effect of mean stress on fatigue life prediction using FEM
- Effect of loading ratio on fatigue life estimation
- Define new material in ANSYS WORKBENCH software
- Solve high-cycle fatigue problems using formula (Part 1)
- Solve high-cycle fatigue problems using formula (Part 2)
- Downloading and installation of ANSYS WORKBENCH and J-Rain Software
- Solve high-cycle fatigue problems by utilizing finite element simulation
- Effect of mean stress on fatigue life prediction using FEM
- Effect of loading ratio on fatigue life estimation
- Improvement of fatigue properties of metallic materials
- Improvement of fatigue properties of metallic materials (Mechanical methods)
- Some new scientific and practical findings
- Effects of SP process on grain size and residual stress
- Effects of SP process on fatigue life
- Thermal operating and Plating
- Machining
- Final video
- Improvement of fatigue properties of metallic materials (Mechanical methods)
- Some new scientific and practical findings
- Effects of SP process on grain size and residual stress
- Effects of SP process on fatigue life
- Thermal operating and Plating
- Machining
- Presentation closing program
- Closing course
- Answers to the Self-check quiz
- References
- Test #6
- Final exam
- Final Quiz
- Self-Check quiz
Summary of User Reviews
Learn about fatigue failure in various fields of engineering with this course. Students have praised the comprehensive content and practical applications of the course. However, some have mentioned that the course can be challenging and overwhelming.Key Aspect Users Liked About This Course
Comprehensive content and practical applicationsPros from User Reviews
- In-depth coverage of fatigue failure in different fields of engineering
- Real-world examples and case studies for practical application
- Engaging and knowledgeable instructors
- Interactive quizzes and assignments to reinforce learning
- Flexible schedule allows for self-paced learning
Cons from User Reviews
- Can be challenging and overwhelming for those with limited engineering background
- Some technical jargon may be difficult to understand
- Limited interaction with instructors and fellow students
- Course material may not be updated regularly
- Lack of hands-on practice or laboratory exercises