Autodesk - Simulation Analysis for Mechanical Engineers with Autodesk Fusion 360
- Offered byCoursera
Simulation Analysis for Mechanical Engineers with Autodesk Fusion 360 at Coursera Overview
Duration | 23 hours |
Start from | Start Now |
Total fee | Free |
Mode of learning | Online |
Difficulty level | Intermediate |
Official Website | Explore Free Course |
Credential | Certificate |
Simulation Analysis for Mechanical Engineers with Autodesk Fusion 360 at Coursera Highlights
- This Course Plus the Full Specialization.
- Shareable Certificates.
- Graded Programming Assignments.
Simulation Analysis for Mechanical Engineers with Autodesk Fusion 360 at Coursera Course details
- The foundation of engineering design is often coupled with validation. Simulation is a great tool that allows engineers to test, validate, and modify designs before they become a physical prototype. When used early in the process for simulation driven design and throughout the development process, simulation can help drive the design, make informed design decisions, speed up time to production, and most importantly, identify and eliminate costly design mistakes.
- Like any other tool though, it must be used properly to yield the best results. In this course, we?ll explore the usage static stress simulation, shape optimization, thermal and other mechanical simulation types to better understand how we can apply these tools to everyday design problems.
- After taking this course, you'll be able to:
- - Describe the simulation workflow in Fusion 360.
- - Summarize the use cases for various types of simulation studies.
- - Demonstrate knowledge and skills in more advanced Fusion 360 CAD and CAE skills.
- - Explain and identify simulation results
Simulation Analysis for Mechanical Engineers with Autodesk Fusion 360 at Coursera Curriculum
Static Stress Simulation
Course overview
Get the software
Week 1 overview
Starting a static stress simulation
Using simplify
Selecting study materials
Creating custom materials
Defining structural constraints
Using a bolted connection
Adding a structural load
Defining multiple load conditions
Solving contact sets
Generating mesh and mesh control
Solving a simulation
Reviewing simulation results
Practice exercise 1 overview
Practice exercise 1 solution
Practice exercise 2 overview
Practice exercise 2 solution
Practice exercise 3 overview
Practice exercise 3 solution
Static Stress Simulation resources
About the discussion forum
Online learning communities and social media
Getting to know your classmates
Practice exercise 1 instructions
Practice exercise 2 instructions
Practice exercise 3 instructions
Week 1 challenge exercise
Pre-course questions
Week 1 quiz
Using Shape Optimization to Drive a Design
Week 2 overview
Defining common parameters for a shape optimization
Defining shape preservation regions
Detailing optimization criteria
Reviewing a shape optimization study
Promoting a mesh to create a new design
Design creation to match a shape optimization mesh
Validation through static stress simulation
Review and refine a design
Practice exercise 1 overview
Practice exercise 1 solution
Practice exercise 2 overview
Practice exercise 2 solution
Practice exercise 3 overview
Practice exercise 3 solution
Using Shape Optimization to Drive a Design resources
Practice exercise 1 instructions
Practice exercise 2 instructions
Practice exercise 3 instructions
Week 2 challenge exercise
Week 2 quiz
Nonlinear Response, Buckling and Modal Frequencies
Week 3 overview
Define and solve a nonlinear static stress study
Review nonlinear results
Refine the model and rerun the study
Define and solve a buckling study
Review and refine a buckling study
Review a final buckling study
Define and solve a modal frequency study
Review modal results
Modify the model to reduce the mass participation
Create a rigid body connector
Explore point masses
Apply additional force types
Simulate pressure
Practice exercise 1 overview
Practice exercise 1 solution
Practice exercise 2 overview
Practice exercise 2 solution
Practice exercise 3 overview
Practice exercise 3 solution
Nonlinear Response, Buckling and Modal Frequencies resources
Practice exercise 1 instructions
Practice exercise 2 instructions
Practice exercise 3 instructions
Week 3 challenge exercise
Week 3 quiz
Thermal and Thermal Stress
Week 4 overview
Prepare a model for thermal simulation
Setting up thermal study materials
Understanding and applying types of thermal loads
Solving a thermal study and reviewing the results
Cloning a simulation model
Setting up a thermal stress study
Setting up mesh and contacts
Modifying a thermal stress study
Event simulation setup
Event simulation results review
Practice exercise 1 overview
Practice exercise 1 solution
Practice exercise 2 overview
Practice exercise 2 solution
Practice exercise 3 overview
Practice exercise 3 solution
Thermal and Thermal Stress resources
Practice exercise 1 instructions
Practice exercise 2 instructions
Practice exercise 3 instructions
Week 4 challenge exercise
Week 4 quiz
Final assessment
Simulation Analysis for Mechanical Engineers with Autodesk Fusion 360 at Coursera Admission Process
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