Practice on Computer Aided Engineering Systems

Course title

Y0149300

	takemura shinichi
	yoshihara shouichirou

Course description

In this section, we would learn material mechanics, mechanical mechanics which is the foundation of CAE (Computer Aided Engineering) through exercises, analyze themselves. Furthermore, through analysis of the phenomenon that deformation and heat are coupled, we would learn the influence of temperature gradient on material deformation. Finally, conduct an optimal design exercise using CAE and understand the necessary conditions for using CAE in practice.

Purpose of class

1. To understand the matters of material dynamics (understanding by a simplified model) by three-dimensional analysis and recognizing the agreement and disagreement between them.
2.To understand the significance and limitations of the material dynamics model, and then using the two- and three-dimensional CAE Learn analytical techniques.

Goals and objectives

To learn CAE method based on finite element method for relationship between deformation and stress, heat transfer and influence of deformation on heat transfer.
To execute and evaluation of these solutions of FEM simulation by using Autodesk-Inventor on deformation, stress and heat transfer.
To understand importance of CAE for design by optimization technique.

Language

Japanese

Class schedule

	Class schedule	HW assignments (Including preparation and review of the class.)	Amount of Time Required
1.	Introduction,Deformation and Stress 1; basic formula, formulation of tension and compression, problem and report-1	Study on Autodesk-Inventor software	60minutes
2.	Deformation and Stress 1; problem and report-2	Study on Autodesk-Inventor software	120minutes
3.	Deformation and Stress 2; bending deformation and stress, problem and report-3	Study on Autodesk-Inventor software	60minutes
4.	Deformation and Stress 2; problem and report -4	Study on Autodesk-Inventor software	120minutes
5.	Deformation and Stress 3; bending deformation using composite material, problem and report-5	Study on Autodesk-Inventor software	60minutes
6.	Deformation and stress 3; problem and report -6	Study on Autodesk-Inventor software	120minutes
7.	Deformation and stress 4; torsional deformation and stress on vessel, problem and report-7	Study on Autodesk-Inventor software	60minutes
8.	Deformation and stress 4; problem and report -8	Study on Autodesk-Inventor software	120minutes
9.	Deformation and Stress-5; review of deformation and stress, problem and report-9	Study on Autodesk-Inventor software	60minutes
10.	Deformation and Stress-5; problem and report -10	Study on Autodesk-Inventor software	120minutes
11.	Deformation and Stress-6; Heat and deformation, problem and report-11	Study on Autodesk-Inventor software	60minutes
12.	Design by CAE; optimal design, problem and report-12	Study on Autodesk-Inventor software	120minutes
13.	Design by CAE; optimal design, problem and report-13	Study on Autodesk-Inventor software	60minutes
14.	Design by CAE; problem and report-14	Study on Autodesk-Inventor software	120minutes
Total.	-	-	1260minutes

Relationship between 'Goals and Objectives' and 'Course Outcomes'

	Study of CAE method	Total.
1.	60%	60%
2.	20%	20%
3.	20%	20%
Total.	100%	-

Evaluation method and criteria

Reports and interview.

Textbooks and reference materials

None specified

Prerequisites

linear algebra

Office hours and How to contact professors for questions

PC mail

Regionally-oriented

Non-regionally-oriented course

Development of social and professional independence

Course that cultivates a basic problem-solving skills

Active-learning course

Most classes are interactive

Course by professor with work experience

Work experience	Work experience and relevance to the course content if applicatable
Applicatable	By using experience of engine mechanism study in automotive company, mechanics of materials using CAE is instructed.

Education related SDGs:the Sustainable Development Goals

4.QUALITY EDUCATION
8.DECENT WORK AND ECONOMIC GROWTH

Last modified : Fri Sep 25 04:04:04 JST 2020