2026Year

Second Semester

Advanced Heat Transfer

Lecture

Advanced Heat Transfer

Z0400004 Advanced Heat Transfer

KOBAYASHI Jun

2.0Credits

Tue.2Period

Hachioji Remote

A) A high degree of specialized expertise　100%
B) The skills to use science and technology　0%
C) The ability to conduct research independently, knowledge pertaining to society and occupations, and sense of ethics required of engineers and researchers　0%
D) Creative skills in specific areas of specialization　0%

Heat transfer phenomena are fundamental processes related to a wide range of fields, mainly energy equipment. From ancient times to today, heat transfer phenomena (eg, boiling of water and melting of ice, etc.) using phase change have been used as a representative example of heat transfer technology under high heat load conditions in industry and everyday life. Even in the modern and near future where energy problems and global environmental problems are mentioned, this heat transfer phenomenon and phase change heat transfer technology occupies an important position as a heat transportation means which is easy, inexpensive and has high capacity (for example, cooling of MPU by heat pipes and ice cold storage etc.). In this lecture, based on thermodynamics, fluid dynamics and heat transfer engineering, the student physically understands and formulates the heat conduction, single phase heat transfer phenomenon and phase change heat transfer phenomenon of vapor and liquid. It aims to understand quantitatively. In addition, by solving several exercises, the student will hone his/her sense of thermal engineering.

Have acquired "Engineering Thermodynamics I and Exercise". It is desirable to take "Heat Transfer".

Project Based Learning／Presentation

1. Outline of Heat Transfer : The second law of thermodynamics and Heat Transfer. Heat Conduction (Fourier's law). Heat Convection (Newton's law of cooling). Radiative Heat Transfer (Stefan-Boltzmann's law)
2. Heat Conduction1: Basic equation of heat conduction. Boundary Condition. One-dimensional steady state heat conduction
3. Heat Conduction2: Two-dimensional steady state heat conduction
4. Heat Conduction3: One-dimensional unsteady state heat conduction
5. Heat Conduction4: Numerical calculation of heat conduction
6. Outline of Heat Convection: Basic equation of heat convection (equation of continuity, Navier-Stokes equation, equation of energy) Boundary Layer. Nondimensionalization. Forced Convection and Natural Convection.
7. Laminar Heat Covectio1: Exact solution. Profile method.
8. Laminar Heat Covectio2: Laminar heat convection in circular pipe. Natural-convection heat transfer
9. Turbulent-Convection Heat Transfer
10. Radiative Heat Transfer1: Electromagnetic wave. Black body. Stefan-Boltzmann's law.
11. Radiative Heat Transfer2: Gray body. Kirchhoff's law. View factor. Radiative heat Transfer
12. Outline of Phase Change: Phase rule. Equation of Clausius-Clapeyron. Equation of van der Waals. Critical Point and Limit of superheat.
13. Nucleate Boiling Heat Transfer: Onset Nucleate Boiling. Bubble dynamics. Critical Heat Flux.
14. Interface stability. Film boiling heat transfer. Minimum Heat Flux. Transition Boiling Heat Transfer. Condensation heat transfer (film-wise condensation and drop-wise condensation).
15. Review of Lecture Content

As a general rule, evaluate with the final exam (report form), and accept credits for people with Grade D or more points.

Basically, I do during schooltime. Further, it also corresponds promptly about the question received on KU-LMS and the mailing received separately.

JSME Textbooks Series -Heat Transfer-, JSME, Maruzen

J. P. Holman, "Heat Transfer", Mcgraw hill (2001.6.1)

For in-person questions or consultations, please visit Room 304, Building 8 during the lunch break (11:40 AM to 12:30 PM) on lecture days (Tuesdays).
For online questions or consultations, please post your question via KU-LMS or contact me by email.

Based on thermodynamics (including chemical thermodynamics), fluid dynamics and heat transfer engineering, knowledge on phase change heat transfer will be developed. In addition, we use fundamental knowledge of gas molecule theory concerning elementary processes of evaporation and condensation and quantum mechanics concerning radiative heat transfer.

Not applicable

Mechanical Engineering Program