In modern society, with the advancement of science, technology, and industrial fields, numerical simulation technology has
become an indispensable tool. By utilizing numerical simulations in the processes of design, analysis, and optimization, it
is possible to reduce costs and shorten time compared to conventional trial-and-error experimental methods. As a result, numerical
simulation has become a fundamental technology in various fields. For students, acquiring numerical simulation skills directly
contributes to enhancing both their specialized knowledge and practical skills. In this course, students will not only learn
theoretical concepts but also gain hands-on experience using actual software and tools to apply simulation techniques in real-world
scenarios. Through this approach, we aim to cultivate professionals who can immediately contribute to the workforce after
graduation.
Perform numerical simulations in the fields of materials mechanics, heat transfer engineering, and mechanical dynamics, which
are essential for manufacturing.
1. Understand the fundamentals of materials mechanics, conduct numerical simulations on basic topics, and compare the results with theoretical solutions.
2. Understand the fundamentals of heat transfer engineering, conduct numerical simulations on basic topics, and compare the results with theoretical solutions.
3. Understand the fundamentals of mechanical dynamics, conduct numerical simulations on basic topics, and compare the results with theoretical solutions.
1. Understand the fundamentals of materials mechanics, conduct numerical simulations on basic topics, and compare the results with theoretical solutions.
2. Understand the fundamentals of heat transfer engineering, conduct numerical simulations on basic topics, and compare the results with theoretical solutions.
3. Understand the fundamentals of mechanical dynamics, conduct numerical simulations on basic topics, and compare the results with theoretical solutions.
- Using Ansys Workbench Mechanical (AWM), students will be able to perform a seamless workflow from model creation to numerical simulation.
- Students will be able to perform calculations for problems in materials mechanics, heat transfer engineering, and mechanical dynamics using both theoretical analysis and numerical simulation methods.
- Students will be able to perform nonlinear analyses, including material nonlinearity, large deformation, and contact, as well as transient analyses such as heat conduction and dynamic analysis.
| Report | Total. | |
|---|---|---|
| 1. | 40% | 40% |
| 2. | 30% | 30% |
| 3. | 30% | 30% |
| Total. | 100% | - |
| Class schedule | HW assignments (Including preparation and review of the class.) | Amount of Time Required | |
|---|---|---|---|
| 1. | Introduction to the Finite Element Method (FEM) and a simple static structural analysis. Exercise 1: Perform the assigned task and submit a report. |
Mastery and review of AWM | 190minutes |
| 2. | Mesh generation and comparison with theoretical solutions. Exercise 2: Perform the assigned task and submit a report. |
Mastery and review of AWM | 190minutes |
| 3. | Introduction to structural analysis and linear analysis. Exercise 3: Perform the assigned task and submit a report. |
Mastery and review of AWM | 190minutes |
| 4. | Elastoplastic analysis. Exercise 4: Perform the assigned task and submit a report. |
Mastery and review of AWM | 190minutes |
| 5. | Contact analysis. Exercise 5: Perform the assigned task and submit a report. |
Mastery and review of AWM | 190minutes |
| 6. | V&V (Comparison with Theoretical Solutions). Exercise 6: Perform the assigned task and submit a report. |
Mastery and review of AWM | 190minutes |
| 7. | Introduction to heat transfer analysis and simple heat transfer analysis. Exercise 7: Perform the assigned task and submit a report. |
Mastery and review of AWM | 190minutes |
| 8. | Steady-state heat transfer analysis. Exercise 8: Perform the assigned task and submit a report. |
Mastery and review of AWM | 190minutes |
| 9. | Transient heat transfer analysis. Exercise 9: Perform the assigned task and submit a report. |
Mastery and review of AWM | 190minutes |
| 10. | Coupled heat transfer-structural analysis. Exercise 10: Perform the assigned task and submit a report. |
Mastery and review of AWM | 190minutes |
| 11. | Introduction to dynamic analysis and simple dynamic analysis. Exercise 11: Perform the assigned task and submit a report. |
Mastery and review of AWM | 190minutes |
| 12. | Modal (eigenvalue) analysis. Exercise 12: Perform the assigned task and submit a report. |
Mastery and review of AWM | 190minutes |
| 13. | Review of analysis methods. Exercise 13: Perform the assigned task and submit a report. |
Mastery and review of AWM | 190minutes |
| 14. | Application to everyday products. Exercise 14: Perform the assigned task and submit a report. |
Mastery and review of AWM | 190minutes |
| Total. | - | - | 2660minutes |
Grades will be assigned based on the reports. A score of 60 points will be given to students who perform an analysis on an
everyday product and obtain reasonable results.
| ways of feedback | specific contents about "Other" |
|---|---|
| Feedback in the class |
Each student should install ANSYS Student on their personal laptop (Windows only) and ensure that it is fully operational
without any issues.
- Course that cultivates a basic problem-solving skills
| Work experience | Work experience and relevance to the course content if applicable |
|---|---|
| Applicable | Engaged in research and development related to numerical simulation at a machinery manufacturer |
- 7.AFFORDABLE AND CLEAN ENERGY
- 9.INDUSTRY, INNOVATION AND INFRASTRUCTURE
Last modified : Wed Feb 19 04:06:16 JST 2025