Course title
4M987000
Advanced Heat Transfer

 yamada jun
Course content
Conductive and Radiative Heat Transfer:

1. Numerical techniques widely used for solving multi-dimensional partial differential equations arising in thermal conductive problem. Numerical solution of steady and time-dependent linear partial differential equations on rectangular domains via finite difference techniques. Linearization methods for treatment of nonlinear problems. FORTRAN programming language is included.
2. Fundamentals of thermal radiation and numerical technique for radiation transfer in scattering and absorbing media
Purpose of class
to foster logical thinking power
Goals and objectives
  1. To learn a technique for numerical simulations using FORTRAN programing language.
  2. To have a skill for developing a computer code for solving multi-dimensional partial differential equations arising in thermal conductive problem.
  3. To understand fundamentals of thermal radiation and to have a skill for solving practical problems on radiation heat transfer.
Language
English
Class schedule

 Class schedule HW assignments (Including preparation and review of the class.) Amount of Time Required
1. Introduction to Numerical simulation,
Mathematical description of physical phenomena 		to read a basic text book for heat transfer 60minutes
2. Fortran programming language to read a basic text book for computational programing 180minutes
3. Fortran programming language to read a basic text book for computational programing 180minutes
4. Discretization method to read the supplied handout 60minutes
5. Steady state one-dimensional conduction to read the supplied handout 300minutes
6. Unteady state one-dimensional conduction to read the supplied handout 180minutes
7. Tridiagonal matrix algorithm to read the supplied handout 60minutes
8. Discretization equation for two-dimensions to read the supplied handout 60minutes
9. Steady state two-dimensional conduction to read the supplied handout 180minutes
10. Unsteady state two-dimensional conduction to read the supplied handout 300minutes
11. Unsteady state two-dimensional conduction to read the supplied handout 300minutes
12. Unsteady state two-dimensional conduction to read the supplied handout 300minutes
13. Fundamentals of thermal radiation to read the supplied handout 120minutes
14. Numerical technique for evaluating radiation transfer in scattering and absorbing media to write a final report 180minutes
Total. - - 2460minutes
Relationship between 'Goals and Objectives' and 'Course Outcomes'

 exercize developed code Total.
1. 30% 0% 30%
2. 30% 30% 60%
3. 10% 0% 10%
Total. 70% 30% -
Evaluation method and criteria
exercise-70%, completeness of the developed numerical code-30%
Textbooks and reference materials
Numerical Heat Transfer and Fluid Flow (Hemisphere Series on Computational Methods in Mechanics and Thermal Science) , S. V. Patankar, Hemisphere Publishing

Radiative Heat Transfer, Michael F. Modest, McGraw-Hill International Edition
Prerequisites
Students should have a level of information literacy that is required as an engineer.
Office hours and How to contact professors for questions
  • pm 12:30 -13:30 on Monday
Relation to the environment
Regionally-oriented
Development of social and professional independence
    Active-learning course
    Last modified : Wed Oct 17 07:13:30 JST 2018