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Dr. Wayne Whiteman, PE
This course explores the analysis and design of beam bending problems.
Read more
This course explores the analysis and design of beam bending problems.
Read more
This course explores the analysis and design of beam bending problems.
Prerequisite Knowledge: You will need to have successfully completed my earlier course “Mechanics of Materials I: Fundamentals of Stress and Strain and Axial Loading” in order to be successful in this course
-------------------------------------------------
The copyright of all content and materials in this course are owned by either the Georgia Tech Research Corporation or Dr. Wayne Whiteman. By participating in the course or using the content or materials, whether in whole or in part, you agree that you may download and use any content and/or material in this course for your own personal, non-commercial use only in a manner consistent with a student of any academic course. Any other use of the content and materials, including use by other academic universities or entities, is prohibited without express written permission of the Georgia Tech Research Corporation. Interested parties may contact Dr. Wayne Whiteman directly for information regarding the procedure to obtain a non-exclusive license.
Register for this course and see more details by visiting:
OpenCourser.com/course/d4d6m4/mechanics
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What's inside
Syllabus
Welcome
Shear Force and Bending Moment Diagrams
In this section, we will review sketching shear force and bending moment diagrams.
Read more
Syllabus
Welcome
Shear Force and Bending Moment Diagrams
In this section, we will review sketching shear force and bending moment diagrams.
Read more
Elastic Beam Bending
In this section, we will learn how to analyze and design for elastic beam bending.
Inelastic beam bending
In this section, we will learn about the analysis and design of inelastic beam bending.
Shear Stresses in Beams subjected to Non-Uniform Loading
In this section, we will learn how to analyze and design for shear stresses in beams subjected to non-uniform loading.
Design of Beams
In this section, we will learn how to design appropriate beams for use in real world engineering structures.
Good to know
Good to know
Know what's good ,
what to watch for , and
possible dealbreakers
Develops the analysis and design of beam bending problems, which is core knowledge in engineering
Builds a solid foundation for understanding elastic beam bending, which is essential for structural engineering
Prerequisite knowledge is required, which may limit accessibility for some learners
Save this course
Save Mechanics of Materials III: Beam Bending to your list so you can find it easily later:
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Reviews summary
Well-received mechanics course
Learners say this course is largely positive, explaining that it offers engaging assignments with difficult exams that are essential to mastery. The course is appreciated for its detailed explanations, which support the well planned lessons and well organized materials. The instructor has a passion for teaching mechanics that shines through each excellent lecture. The course is recommended for students seeking a strong foundation in Mechanics of Materials.
Course is challenging
"challenging and taught me new skills and techniques"
Challenging assignments push you to think deeply
"difficult exams"
Covers beam bending thoroughly
"detailed explanations"
"well planned lessons and well organized materials"
Real-world examples connect concepts to real life
"helped explain things in which are harder to understand"
"good complement to my graduation"
Lessons and materials are concise and well organized
"not so lengthy modules"
"lessons are well organised"
"Technical skill and knowledge develops as one progresses in the course."
"Theory is very well explained and real engineering problems are used to provide first hand experience"
Instructor is experienced and passionate
"passion for teaching mechanics"
"excellent lectures"
Concepts are well explained and well delivered
"easy to understand and the teaching is really simple and clear"
"explained the things in an easily understandable and more application oriented manner"
"makes the complicated physics easy to understand and relate it with real life examples"
May be too basic for experts
"For a civil engineer (building), the course will be simple."
"The entire course was completed in about 6 hours."
Activities
Be better prepared
before
your course. Deepen your understanding
during
and
after
it. Supplement your coursework and achieve mastery of the topics covered
in Mechanics of Materials III: Beam Bending with these
activities:
Refresh Mechanics of Materials
Show steps
Review the concepts of mechanics of materials to strengthen your foundation for this course.
Browse courses on
Mechanics of Materials
Show steps
-
Review your notes and textbooks from previous mechanics of materials courses.
-
Solve practice problems related to stress, strain, and axial loading.
Find a Mentor
Show steps
Reach out to professionals in the field of beam bending and structural design to gain insights and guidance.
Show steps
-
Identify potential mentors who have expertise in beam bending and structural design.
-
Contact the mentors and express your interest in learning from them.
Study Group
Show steps
Form a study group with classmates to discuss course concepts and work on problems together.
Show steps
-
Find classmates who are also enrolled in the course.
-
Schedule regular study sessions to discuss course material and work on problems.
Five other activities
Expand to see all activities and additional details
Show all eight activities
Shear Force and Bending Moment Diagrams
Show steps
Practice sketching shear force and bending moment diagrams to reinforce understanding of these concepts in beam bending.
Show steps
-
Review the concept of shear force and bending moment diagrams.
-
Solve practice problems involving the determination of shear force and bending moment diagrams for simple beams.
Elastic Beam Bending
Show steps
Create a presentation or video tutorial that explains the analysis and design of elastic beam bending.
Show steps
-
Review the theory of elastic beam bending.
-
Derive the governing equations for elastic beam bending.
-
Apply the governing equations to analyze and design elastic beams.
Inelastic Beam Bending
Show steps
Practice analyzing and designing inelastic beam bending to understand the behavior of beams beyond the elastic limit.
Show steps
-
Review the concept of inelastic beam bending.
-
Analyze and design beams subjected to inelastic bending.
Shear Stresses in Beams
Show steps
Create a poster or infographic that summarizes the analysis and design of shear stresses in beams.
Show steps
-
Review the theory of shear stresses in beams.
-
Derive the governing equations for shear stresses in beams.
-
Apply the governing equations to analyze and design beams for shear stresses.
Beam Design
Show steps
Design an appropriate beam for use in a real-world engineering structure.
Browse courses on
Beam Design
Show steps
-
Identify the requirements for the beam.
-
Select an appropriate beam section.
-
Check the beam for strength and deflection.
-
Detail the beam connections.
Refresh Mechanics of Materials
Show steps
Review the concepts of mechanics of materials to strengthen your foundation for this course.
Browse courses on
Mechanics of Materials
Show steps
Show steps
Show steps
- Review your notes and textbooks from previous mechanics of materials courses.
- Solve practice problems related to stress, strain, and axial loading.
Find a Mentor
Show steps
Reach out to professionals in the field of beam bending and structural design to gain insights and guidance.
Show steps
Show steps
Show steps
- Identify potential mentors who have expertise in beam bending and structural design.
- Contact the mentors and express your interest in learning from them.
Study Group
Show steps
Form a study group with classmates to discuss course concepts and work on problems together.
Show steps
Show steps
Show steps
- Find classmates who are also enrolled in the course.
- Schedule regular study sessions to discuss course material and work on problems.
Five other activities
Expand to see all activities and additional details
Show all eight activities
Shear Force and Bending Moment Diagrams
Show steps
Practice sketching shear force and bending moment diagrams to reinforce understanding of these concepts in beam bending.
Show steps
Show steps
Show steps
- Review the concept of shear force and bending moment diagrams.
- Solve practice problems involving the determination of shear force and bending moment diagrams for simple beams.
Elastic Beam Bending
Show steps
Create a presentation or video tutorial that explains the analysis and design of elastic beam bending.
Show steps
Show steps
Show steps
- Review the theory of elastic beam bending.
- Derive the governing equations for elastic beam bending.
- Apply the governing equations to analyze and design elastic beams.
Inelastic Beam Bending
Show steps
Practice analyzing and designing inelastic beam bending to understand the behavior of beams beyond the elastic limit.
Show steps
Show steps
Show steps
- Review the concept of inelastic beam bending.
- Analyze and design beams subjected to inelastic bending.
Shear Stresses in Beams
Show steps
Create a poster or infographic that summarizes the analysis and design of shear stresses in beams.
Show steps
Show steps
Show steps
- Review the theory of shear stresses in beams.
- Derive the governing equations for shear stresses in beams.
- Apply the governing equations to analyze and design beams for shear stresses.
Beam Design
Show steps
Design an appropriate beam for use in a real-world engineering structure.
Browse courses on
Beam Design
Show steps
Show steps
Show steps
- Identify the requirements for the beam.
- Select an appropriate beam section.
- Check the beam for strength and deflection.
- Detail the beam connections.
Career center
Learners who complete Mechanics of Materials III: Beam Bending will develop knowledge and skills
that may be useful to these careers:
Structural Engineer
Structural Engineer
Structural Engineers analyze and design the structural components of buildings, bridges, and other structures. They use their knowledge of mechanics of materials to ensure that these structures can withstand the forces they will be subjected to, such as gravity, wind, and earthquakes. The Mechanics of Materials III: Beam Bending course can help Structural Engineers develop the skills they need to analyze and design beams, which are one of the most common structural components used in construction.
Civil Engineer
Civil Engineer
Civil Engineers design and build infrastructure projects such as roads, bridges, and buildings. They use their knowledge of mechanics of materials to ensure that these projects are safe and durable. The Mechanics of Materials III: Beam Bending course can help Civil Engineers develop the skills they need to analyze and design beams, which are one of the most common structural components used in construction.
Mechanical Engineer
Mechanical Engineer
Mechanical Engineers design and build machines and other mechanical devices. They use their knowledge of mechanics of materials to ensure that these devices are safe and efficient. The Mechanics of Materials III: Beam Bending course can help Mechanical Engineers develop the skills they need to analyze and design beams, which are one of the most common structural components used in machines.
Aerospace Engineer
Aerospace Engineer
Aerospace Engineers design and build aircraft, spacecraft, and other aerospace vehicles. They use their knowledge of mechanics of materials to ensure that these vehicles are safe and efficient. The Mechanics of Materials III: Beam Bending course can help Aerospace Engineers develop the skills they need to analyze and design beams, which are one of the most common structural components used in aerospace vehicles.
Materials Engineer
Materials Engineer
Materials Engineers develop and test new materials for use in a variety of applications. They use their knowledge of mechanics of materials to understand the properties of these materials and how they will perform under different conditions. The Mechanics of Materials III: Beam Bending course can help Materials Engineers develop the skills they need to analyze and design beams, which are one of the most common structural components used in a variety of applications.
Product Designer
Product Designer
Product Designers create and develop new products. They use their knowledge of mechanics of materials to ensure that these products are safe and functional. The Mechanics of Materials III: Beam Bending course can help Product Designers develop the skills they need to analyze and design beams, which are one of the most common structural components used in a variety of products.
Construction Manager
Construction Manager
Construction Managers oversee the construction of buildings and other structures. They use their knowledge of mechanics of materials to ensure that these projects are built safely and efficiently. The Mechanics of Materials III: Beam Bending course can help Construction Managers develop the skills they need to analyze and design beams, which are one of the most common structural components used in construction.
Architect
Architect
Architects design buildings and other structures. They use their knowledge of mechanics of materials to ensure that these structures are safe and aesthetically pleasing. The Mechanics of Materials III: Beam Bending course can help Architects develop the skills they need to analyze and design beams, which are one of the most common structural components used in construction.
Forensic Engineer
Forensic Engineer
Forensic Engineers investigate the causes of failures in buildings and other structures. They use their knowledge of mechanics of materials to determine why these failures occurred and how they can be prevented in the future. The Mechanics of Materials III: Beam Bending course can help Forensic Engineers develop the skills they need to analyze and design beams, which are one of the most common structural components used in construction.
Geotechnical Engineer
Geotechnical Engineer
Geotechnical Engineers design and build foundations for buildings and other structures. They use their knowledge of mechanics of materials to ensure that these foundations are safe and stable. The Mechanics of Materials III: Beam Bending course can help Geotechnical Engineers develop the skills they need to analyze and design beams, which are one of the most common structural components used in foundations.
Materials Scientist
Materials Scientist
Materials Scientists develop and test new materials for use in a variety of applications. They use their knowledge of mechanics of materials to understand the properties of these materials and how they will perform under different conditions. The Mechanics of Materials III: Beam Bending course can help Materials Scientists develop the skills they need to analyze and design beams, which are one of the most common structural components used in a variety of applications.
Naval Architect
Naval Architect
Naval Architects design and build ships and other marine vessels. They use their knowledge of mechanics of materials to ensure that these vessels are safe and seaworthy. The Mechanics of Materials III: Beam Bending course can help Naval Architects develop the skills they need to analyze and design beams, which are one of the most common structural components used in ships and other marine vessels.
Petroleum Engineer
Petroleum Engineer
Petroleum Engineers design and build equipment and systems for the extraction and production of oil and gas. They use their knowledge of mechanics of materials to ensure that this equipment and these systems are safe and efficient. The Mechanics of Materials III: Beam Bending course can help Petroleum Engineers develop the skills they need to analyze and design beams, which are one of the most common structural components used in this equipment and these systems.
Robotics Engineer
Robotics Engineer
Robotics Engineers design and build robots. They use their knowledge of mechanics of materials to ensure that these robots are safe and efficient. The Mechanics of Materials III: Beam Bending course can help Robotics Engineers develop the skills they need to analyze and design beams, which are one of the most common structural components used in robots.
Teacher
Teacher
Teachers educate students in a variety of subjects. They use their knowledge of mechanics of materials to teach students about the properties of materials and how they are used in the design and construction of buildings and other structures. The Mechanics of Materials III: Beam Bending course can help Teachers develop the skills they need to teach students about beams, which are one of the most common structural components used in construction.
For more career information including salaries, visit:
OpenCourser.com/course/d4d6m4/mechanics
Reading list
We've selected 18 books
that we think will supplement your
learning. Use these to
develop background knowledge, enrich your coursework, and gain a
deeper understanding of the topics covered in
Mechanics of Materials III: Beam Bending.
Classic textbook on the mechanics of materials. It provides a comprehensive overview of the subject, and valuable resource for students and professionals alike. This book comprehensive reference on the mechanics of materials, and valuable resource for students and professionals alike.
Is the widely adopted textbook for a first course in Mechanics of Materials teaching methods based on both the theory and applications. It is more comprehensive than other books in the field.
Is an exhaustive reference tool for engineers who calculate and design members for structures and machines in compliance with safety standards.
Covers advanced topics in mechanics of materials such as failure theories and energy methods. It could provide more background and depth to beam bending.
Comprehensive reference on mechanical engineering design. It valuable resource for students and professionals alike.
This textbook provides a clear and thorough treatment of the theory of elasticity with a focus on engineering applications. It could serve as a valuable reference for students who want to strengthen their understanding of the subject.
Provides a comprehensive overview of the theory of elasticity. It valuable resource for students and professionals who need a deeper understanding of the subject.
Classic textbook on the theory of elasticity. It valuable resource for students and professionals who need a deeper understanding of the subject.
Save
Provides a comprehensive overview of solid mechanics, including beam bending. It could serve as a valuable resource for students who want to explore the subject in more depth.
Provides a simplified and accessible introduction to mechanics of materials. It could be helpful for learners who want to build a foundation in the subject.
Provides a comprehensive overview of the computational mechanics of solids. It valuable resource for students and professionals who need to use computational mechanics to analyze solids.
Simplified overview of the mechanics of materials. It valuable resource for students who are new to the subject.
More introductory treatment of the mechanics of materials. It valuable resource for students who are new to the subject.
More introductory treatment of the mechanics of materials. It valuable resource for students who are new to the subject.
More advanced treatment of the mechanics of materials. It valuable resource for students and professionals who need a deeper understanding of the subject.
More introductory treatment of the mechanics of materials. It valuable resource for students who are new to the subject.
More advanced treatment of the mechanics of materials. It valuable resource for students and professionals who need a deeper understanding of the subject.
More advanced treatment of the mechanics of materials. It valuable resource for students and professionals who need a deeper understanding of the subject.
For more information about how these books relate to this course, visit:
OpenCourser.com/course/d4d6m4/mechanics
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Effort
5 weeks of material; 5 to 7 hours per week work for students
Level
Intermediate
Via
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Institution
Georgia Institute of Technology
Instructor
Dr. Wayne Whiteman, PE
Language
English
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Good to know
Develops the analysis and design of beam bending problems, which is core knowledge in engineering
Builds a solid foundation for understanding elastic beam bending, which is essential for structural engineering
Prerequisite knowledge is required, which may limit accessibility for some learners
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