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Heat Transfer Semester 5 (TE Third Year) BE Mechanical Engineering University of Mumbai Topics and Syllabus

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University of Mumbai Syllabus For Semester 5 (TE Third Year) Heat Transfer: Knowing the Syllabus is very important for the students of Semester 5 (TE Third Year). Shaalaa has also provided a list of topics that every student needs to understand.

The University of Mumbai Semester 5 (TE Third Year) Heat Transfer syllabus for the academic year 2021-2022 is based on the Board's guidelines. Students should read the Semester 5 (TE Third Year) Heat Transfer Syllabus to learn about the subject's subjects and subtopics.

Students will discover the unit names, chapters under each unit, and subtopics under each chapter in the University of Mumbai Semester 5 (TE Third Year) Heat Transfer Syllabus pdf 2021-2022. They will also receive a complete practical syllabus for Semester 5 (TE Third Year) Heat Transfer in addition to this.

CBCGS [2018 - current]
CBGS [2014 - 2017]
Old [2000 - 2013]

University of Mumbai Semester 5 (TE Third Year) Heat Transfer Revised Syllabus

University of Mumbai Semester 5 (TE Third Year) Heat Transfer and their Unit wise marks distribution

University of Mumbai Semester 5 (TE Third Year) Heat Transfer Course Structure 2021-2022 With Marking Scheme

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Syllabus

C Module 1
C Module 1
101 Introduction
  • Typical heat transfer situations, Modes of heat transfer,
  • heat transfer parameters, various thermo physical properties.
101 Introduction
  • Typical heat transfer situations, Modes of heat transfer,
  • heat transfer parameters, various thermo physical properties.
CC Module 2
CC Module 2
201 Conduction
  • Fourier’s law of heat conduction,
  • thermal conductivity,
  • differential equation of heat conduction with heat generation in unsteady state in the Cartesian coordinate system,
  • Boundary and initial conditions,
  • Solution to three dimensional steady heat conduction problems,
  • Steady heat conduction in plane walls, composite walls,
  • Concept of thermal resistance and thermal resistance network,
  • Heat conduction in cylinders and spheres,
  • Differential equation of heat conduction in cylindrical co-ordinates,
  • Conduction through Cylindrical and Spherical composite walls (Derivation NOT INCLUDED for Spherical walls),
  • Critical thickness/radius of insulation and its importance.
201 Conduction
  • Fourier’s law of heat conduction,
  • thermal conductivity,
  • differential equation of heat conduction with heat generation in unsteady state in the Cartesian coordinate system,
  • Boundary and initial conditions,
  • Solution to three dimensional steady heat conduction problems,
  • Steady heat conduction in plane walls, composite walls,
  • Concept of thermal resistance and thermal resistance network,
  • Heat conduction in cylinders and spheres,
  • Differential equation of heat conduction in cylindrical co-ordinates,
  • Conduction through Cylindrical and Spherical composite walls (Derivation NOT INCLUDED for Spherical walls),
  • Critical thickness/radius of insulation and its importance.
CCC Module 3
CCC Module 3
301 Extended Surfaces
  • Heat transfer from finned surfaces, Types of fins,
  • Fin equation for rectangular fin and its solution,
  • Fin efficiency, Fin effectiveness.
302 Transient Heat Conduction
  • Lumped system analysis, One dimensional transient problems analytical solutions,
  • One dimensional Heisler charts
303 Numerical Methods in Conduction
  • Importance of numerical methods,
  • Finite difference formulation of one dimensional steady heat conduction equations.
301 Extended Surfaces
  • Heat transfer from finned surfaces, Types of fins,
  • Fin equation for rectangular fin and its solution,
  • Fin efficiency, Fin effectiveness.
302 Transient Heat Conduction
  • Lumped system analysis, One dimensional transient problems analytical solutions,
  • One dimensional Heisler charts
303 Numerical Methods in Conduction
  • Importance of numerical methods,
  • Finite difference formulation of one dimensional steady heat conduction equations.
CD Module 4
CD Module 4
401 Convection
  • Physical mechanism of convection, Natural and Forced convection, Velocity/hydrodynamic and Thermal boundary layer, Velocity and temperature profile, Differential equation of heat convection, Laminar flow heat transfer in circular pipe, constant heat flux and constant wall temperature, thermal entrance region, Turbulent flow heat transfer in circular pipes, Pipes of other cross sections, Heat transfer in laminar and turbulent flow over a flat plate, Heat pipe introduction and applications, Principles of dimensional analysis and its application in convective heat transfer, Empirical correlations for convection, Physical significance of various dimensionless numbers useful in natural and forced convection.
401 Convection
  • Physical mechanism of convection, Natural and Forced convection, Velocity/hydrodynamic and Thermal boundary layer, Velocity and temperature profile, Differential equation of heat convection, Laminar flow heat transfer in circular pipe, constant heat flux and constant wall temperature, thermal entrance region, Turbulent flow heat transfer in circular pipes, Pipes of other cross sections, Heat transfer in laminar and turbulent flow over a flat plate, Heat pipe introduction and applications, Principles of dimensional analysis and its application in convective heat transfer, Empirical correlations for convection, Physical significance of various dimensionless numbers useful in natural and forced convection.
D Module 5
D Module 5
501 Radiation
  • Thermal radiation, Blackbody radiation, Radiation intensity,
  • Radiative properties, Basic laws of radiation
  • Plank’s law,
  • Kirchoff’s law,
  • StefanBoltzman law,
  • Wien’s displacement law,
  • Lambert’s cosine law,
  • Radiation exchange between black surfaces,
  • Shape factor, Radiation exchange between gray surfaces,
  • Radiosity- Irradiation method, Radiation shield and the radiation effect
501 Radiation
  • Thermal radiation, Blackbody radiation, Radiation intensity,
  • Radiative properties, Basic laws of radiation
  • Plank’s law,
  • Kirchoff’s law,
  • StefanBoltzman law,
  • Wien’s displacement law,
  • Lambert’s cosine law,
  • Radiation exchange between black surfaces,
  • Shape factor, Radiation exchange between gray surfaces,
  • Radiosity- Irradiation method, Radiation shield and the radiation effect
DC Module 6
DC Module 6
601 Boiling and Condensation
  • Boiling heat transfer, Pool boiling, Flow boiling,
  • Condensation heat transfer,
  • Film condensation, Dropwise condensation
602 Heat Exchangers
  • Types of heat exchangers, Overall heat transfer coefficient,
  • Analysis of heat exchangers, LMTD method, Effectiveness-NTU method,
  • Correction factor and effectiveness of heat exchangers
601 Boiling and Condensation
  • Boiling heat transfer, Pool boiling, Flow boiling,
  • Condensation heat transfer,
  • Film condensation, Dropwise condensation
602 Heat Exchangers
  • Types of heat exchangers, Overall heat transfer coefficient,
  • Analysis of heat exchangers, LMTD method, Effectiveness-NTU method,
  • Correction factor and effectiveness of heat exchangers
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