Heat and Mass Transfer Syllabus

Heat and Mass Transfer Syllabus

1. Introduction to Heat Transfer

  • Modes of heat transfer: Conduction, convection, and radiation
  • Basic laws and principles

2. Conduction

  • Fourier’s law of heat conduction
  • Steady-state and transient conduction
  • One-dimensional and multi-dimensional conduction
  • Thermal resistance and insulation

3. Convection

  • Newton’s law of cooling
  • Forced and natural convection
  • Laminar and turbulent flow
  • Heat transfer in internal and external flows
  • Empirical correlations for heat transfer coefficients

4. Radiation

  • Basic concepts of thermal radiation
  • Stefan-Boltzmann law
  • Blackbody and greybody radiation
  • View factors and radiation exchange between surfaces

5. Heat Exchangers

  • Types of heat exchangers
  • Design and analysis of heat exchangers
  • Effectiveness-NTU method
  • LMTD method

6. Mass Transfer

  • Fick’s law of diffusion
  • Steady-state diffusion
  • Convective mass transfer
  • Analogies between heat and mass transfer

7. Boiling and Condensation

  • Boiling heat transfer: Pool boiling and flow boiling
  • Condensation heat transfer: Film and dropwise condensation

8. Numerical Methods in Heat and Mass Transfer

  • Finite difference methods
  • Numerical solutions for conduction and convection problems

9. Laboratory Work and Projects

  • Experiments on conduction, convection, and radiation
  • Heat exchanger performance testing
  • Computational simulations

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