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.
Este curso faz parte do Programa de cursos integrados Autodesk CAD/CAM/CAE for Mechanical Engineering
Simulation Analysis for Mechanical Engineers with Autodesk Fusion 360
oferecido por
Informações sobre o curso
4,234 visualizações recentes
O que você vai aprender
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
Habilidades que você terá
AutodeskSimulationFusion 360Engineering DesignMechanical Engineering
Certificados compartilháveis
Tenha o certificado após a conclusão
100% on-line
Comece imediatamente e aprenda em seu próprio cronograma.
Prazos flexíveis
Redefinir os prazos de acordo com sua programação.
Nível intermediário
Aprox. 10 horas para completar
Sugerido: 4 weeks of study
Inglês
Legendas: Inglês
Programa - O que você aprenderá com este curso
5 horas para concluir
Static Stress Simulation
In Week 1, we’ll explore the setup, solve, and understanding surrounding static stress simulations. Starting with the basics and moving to more advanced tools such as bolted connections we’ll walk through how to prepare and process a static simulation.
5 horas para concluir
21 vídeos (Total 66 mín.), 8 leituras, 2 testes
21 videos
Get the software2min
Week 1 overview40s
Starting a static stress simulation4min
Using simplify4min
Selecting study materials2min
Creating custom materials6min
Defining structural constraints3min
Using a bolted connection2min
Adding a structural load3min
Defining multiple load conditions2min
Solving contact sets3min
Generating mesh and mesh control7min
Solving a simulation2min
Reviewing simulation results10min
Practice exercise 1 overview21s
Practice exercise 1 solution1min
Practice exercise 2 overview15s
Practice exercise 2 solution1min
Practice exercise 3 overview26s
Practice exercise 3 solution3min
8 leituras
Static Stress Simulation resources5min
About the discussion forum5min
Online learning communities and social media10min
Getting to know your classmates10min
Practice exercise 1 instructions30min
Practice exercise 2 instructions30min
Practice exercise 3 instructions30min
Week 1 challenge exercise1h 30min
2 exercícios práticos
Pre-course questions10min
Week 1 quiz10min
4 horas para concluir
Using Shape Optimization to Drive a Design
In Week 2, we’ll cover shape optimization simulation study type to explore load paths in designs. This simulation study will help engineers identify critical load paths in a design to make more informed decisions on material removal.
4 horas para concluir
15 vídeos (Total 53 mín.), 5 leituras, 1 teste
15 videos
Defining common parameters for a shape optimization6min
Defining shape preservation regions2min
Detailing optimization criteria3min
Reviewing a shape optimization study4min
Promoting a mesh to create a new design3min
Design creation to match a shape optimization mesh8min
Validation through static stress simulation4min
Review and refine a design7min
Practice exercise 1 overview16s
Practice exercise 1 solution3min
Practice exercise 2 overview15s
Practice exercise 2 solution3min
Practice exercise 3 overview22s
Practice exercise 3 solution3min
5 leituras
Using Shape Optimization to Drive a Design resources5min
Practice exercise 1 instructions30min
Practice exercise 2 instructions30min
Practice exercise 3 instructions30min
Week 2 challenge exercise1h 30min
1 exercício prático
Week 2 quiz10min
5 horas para concluir
Nonlinear Response, Buckling and Modal Frequencies
In Week 3, we’ll focus on some additional simulation study types in Fusion 360, namely nonlinear response, structural buckling and modal frequencies. These study types allow for greater insight into structural and mechanical problems associated with a wide variety of designs. We will focus on various aspects of our gear reduction assembly as well as explore other examples suited for these types of simulations.
5 horas para concluir
20 vídeos (Total 64 mín.), 5 leituras, 1 teste
20 videos
Define and solve a nonlinear static stress study6min
Review nonlinear results2min
Refine the model and rerun the study3min
Define and solve a buckling study2min
Review and refine a buckling study2min
Review a final buckling study1min
Define and solve a modal frequency study3min
Review modal results2min
Modify the model to reduce the mass participation5min
Create a rigid body connector4min
Explore point masses9min
Apply additional force types4min
Simulate pressure7min
Practice exercise 1 overview15s
Practice exercise 1 solution1min
Practice exercise 2 overview18s
Practice exercise 2 solution1min
Practice exercise 3 overview18s
Practice exercise 3 solution1min
5 leituras
Nonlinear Response, Buckling and Modal Frequencies resources5min
Practice exercise 1 instructions30min
Practice exercise 2 instructions30min
Practice exercise 3 instructions30min
Week 3 challenge exercise2h 30min
1 exercício prático
Week 3 quiz10min
7 horas para concluir
Thermal and Thermal Stress
In Week 4, we’ll explore and compare the effects of thermal and thermal stresses on designs. Temperature and heat can be a major factor in the failure of a design so exploring a design’s performance can lead to better informed design decisions. As a bonus, we’ll also look at event simulation and how a design performs when subject to motion and how it responds to an impact.
7 horas para concluir
17 vídeos (Total 73 mín.), 5 leituras, 3 testes
17 videos
Prepare a model for thermal simulation4min
Setting up thermal study materials2min
Understanding and applying types of thermal loads6min
Solving a thermal study and reviewing the results8min
Cloning a simulation model11min
Setting up a thermal stress study4min
Setting up mesh and contacts4min
Modifying a thermal stress study6min
Event simulation setup8min
Event simulation results review6min
Practice exercise 1 overview13s
Practice exercise 1 solution2min
Practice exercise 2 overview15s
Practice exercise 2 solution2min
Practice exercise 3 overview20s
Practice exercise 3 solution2min
5 leituras
Thermal and Thermal Stress resources5min
Practice exercise 1 instructions30min
Practice exercise 2 instructions30min
Practice exercise 3 instructions30min
Week 4 challenge exercise1h 30min
2 exercícios práticos
Week 4 quiz10min
Final assessment40min
oferecido por
Autodesk
Today's challenges will be solved by tomorrow's designers. That's why Autodesk gives students, educators, and educational institutions free access to our design software, creativity apps, and learning resources. A market leader for more than 30 years, Autodesk offers the broadest and deepest portfolio of products in the design world. Autodesk helps people imagine, design and create a better world. Everyone—from design professionals, engineers and architects to digital artists, students and hobbyists—uses Autodesk software to unlock their creativity and solve important challenges.
Sobre Programa de cursos integrados Autodesk CAD/CAM/CAE for Mechanical Engineering
The demand placed on today’s engineers goes above and beyond the job description. Products have become complex and engineers are more frequently asked to leave specialized roles and to take on a wide variety of tasks that are beyond their traditional responsibilities. These tasks are centered on form, fit, and function. Engineers need to factor in broader concerns such as cost, procurement, sustainability, manufacturability, and serviceability. Their role has moved away from an individual responsibility to working as part of a collaborative engineering team, executing tradeoffs with both engineering and business stakeholders to meet project goals. These trends have forced today’s engineers to broaden their skillset to be successful.
Engineers today are required to be on the cutting edge of design innovation. This means not only understanding engineering principles that govern the title and role, but also perfecting the toolsets needed to design and develop products.
Through this specialization, you’ll learn the foundations of applying computer aided design (CAD), computer aided engineering (CAE), and manufacturing principles while developing your technical skills within Autodesk Fusion 360.
Perguntas Frequentes – FAQ
Quando terei acesso às palestras e às tarefas?
Ao se inscrever para um Certificado, você terá acesso a todos os vídeos, testes e tarefas de programação (se aplicável). Tarefas avaliadas pelos colegas apenas podem ser enviadas e avaliadas após o início da sessão. Caso escolha explorar o curso sem adquiri-lo, talvez você não consiga acessar certas tarefas.
O que recebo ao me inscrever nesta Especialização?
Quando você se inscreve no curso, tem acesso a todos os cursos na Especialização e pode obter um certificado quando concluir o trabalho. Seu Certificado eletrônico será adicionado à sua página de Participações e você poderá imprimi-lo ou adicioná-lo ao seu perfil no LinkedIn. Se quiser apenas ler e assistir o conteúdo do curso, você poderá frequentá-lo como ouvinte sem custo.
Qual é a política de reembolso?
Existe algum auxílio financeiro disponível?
How to I access Autodesk® Fusion 360™ as a student or educator?
How to I access a Fusion 360 as a professional?
Will I earn any type of achievement by completing this course?
What are the system requirements for Fusion 360?
How do I get installation support for Fusion 360?
How do I share my designs on the Autodesk Fusion gallery?
How do I become an Autodesk Certified User?
How do I continue building my Fusion 360 knowledge and skills once I complete the course?
Do I have the option to access these learning materials for free?
Mais dúvidas? Visite o Central de Ajuda ao Aprendiz.