Numerical Thermofluid Analysis

Course title

B0020400

Click to show questionnaire result at 2018

Course description

Fluid flow phenomena are widely observed in nature and human life. Actual flow in reality is so complicated that purely theoretical analysis is very difficult to apply. Therefore, numerical (computational) analysis is often employed in industry. In this class, basic knowledge about numerical technique for analysis of heat transfer and fluid flow, and workshops by using commercial software package are provided.

Purpose of class

Basic knowledge on numerical method in thermofluid engineering, and fundamental skill in computational technique by using actual software package will be provided.

Goals and objectives

Numerical method about differenctial equation
Basic knowledge about numerical technique for heat conduction and fluid flow problems
Simulation practice of modelling, calculation, graphical output by using a practical software package.

Language

Japanese

Class schedule

	Class schedule	HW assignments (Including preparation and review of the class.)	Amount of Time Required
1.	Outline of the lecuture Differential equation	Review about differential equation	190minutes
2.	Finite difference method Ordinary differential equation Least mean square method	Preview of the handout material	190minutes
3.	Regular falsi method Numerical integration method	Preview of the sample programs	190minutes
4.	Conservation equation and finite difference method Equation of continuity	Review of conservation equations	190minutes
5.	Energy transport equation Euler method and Runge-Kutta method Tri Diagonal Matrics Algorighm (TDMA) method	Preview of the handout material	190minutes
6.	Practice on Euler method and Runge-Kutta method Practice on numerical integration	Preview of the handout material	190minutes
7.	One dimensional heat conduction problem	Review of heat conduction theory	190minutes
8.	Practice of one dimensional heat conduction problem	Preview of the handout material	190minutes
9.	Two dimensional heat conduction problem (outline)	Preview of the handout material	190minutes
10.	Numerical method for thermofluid problem About packaged software for Computational Fluid Dynamics (CFD)	Obtain basic information about CFD	190minutes
11.	Introduction and practice of CFD software	Preview of the handout material	190minutes
12.	Practice on one/two dimensional heat conduction problems by the software Practice on fluid flow problem by the software	Preparation of sample problems to practice on by using CFD software	190minutes
13.	Lecture on numerical method in fluid flow problem	Preview of the handout material	190minutes
14.	Final examination	Review of quiz and report paper materials	190minutes
Total.	-	-	2660minutes

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

	quiz	report papers	examination	Total.
1.	10%	5%	20%	35%
2.	10%	5%	20%	35%
3.	0%	20%	10%	30%
Total.	20%	30%	50%	-

Evaluation method and criteria

Quiz (20 %), Report papers (30 %), Final examination (50 %)
Total is 100 %.
The points >= 60 % are approved to give credit.

Textbooks and reference materials

Necessary handouts will be given in class.

Prerequisites

Fluid mechanics, heat transfer

Office hours and How to contact professors for questions

Monday, 16:50~18:30. Appointment in advance is preferable.

Relation to the environment

Non-environment-related course

Regionally-oriented

Non-regionally-oriented course

Development of social and professional independence

Course that cultivates an ability for utilizing knowledge
Course that cultivates a basic self-management skills

Active-learning course

More than one class is interactive

Course by professor with work experience

Work experience	Work experience and relevance to the course content if applicatable
Applicatable	The professor used to work on R&D in semiconductor industry. The research was related to fluid mechanics and heat transfer with numerical simulations.

Last modified : Thu Mar 21 14:27:02 JST 2019