Heat and Mass Transfer Auto 6th Sem Syllabus for VTU BE 2017 Scheme

Heat and Mass Transfer detail syllabus for Automobile Engineering (Auto), 2017 scheme is taken from VTU official website and presented for VTU students. The course code (17AU62), and for exam duration, Teaching Hr/week, Practical Hr/week, Total Marks, internal marks, theory marks, duration and credits do visit complete sem subjects post given below.

For all other auto 6th sem syllabus for be 2017 scheme vtu you can visit Auto 6th Sem syllabus for BE 2017 Scheme VTU Subjects. The detail syllabus for heat and mass transfer is as follows.

Course Objectives:

At the end of the course, students will be able to

• Explain fundamental principles and laws of conduction, convection and radiation modes of heat transfer.
• Analyze one dimensional steady state heat transfer.
• Analyze one dimensional one dimensional unsteady state heat transfer.
• Analyze one dimensional forced convection heat transfer problems.
• Analyze one dimensional free convection heat transfer problems.
• Analyze one dimensional application like flow over flat plate etc.
• Introduce basic principle of heat exchanger analysis and thermal design.
• Apply laws of radiation heat transfer to solve engineering problems.

Module 1

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Module 2

Variable Thermal Conductivity: Derivation for heat flow and temperature distribution in plane wall. Critical thickness of insulation without heat generation, Heat transfer in extended surfaces of uniform cross-section without heat generation, Long fin, and short fin with insulated tip and without insulated tip and fin connected between two heat sources. Fin efficiency and effectiveness. Numerical problems. One-dimensional Transient Conduction: Conduction in solids with negligible internal temperature gradient (Lumped system analysis), Use of Transient temperature charts (Heisler’s charts) for transient conduction in slab, long cylinder and sphere; use of transient temperature charts for transient conduction in semi-infinite solids. Numerical Problems.

Module 3

Concepts and Basic Relations in Boundary Layers:
Flow over a body velocity boundary layer; critical Reynolds number; general expressions for drag coefficient and drag force; thermal boundary layer; general expression for local heat transfer coefficient; Average heat transfer coefficient; Nusselt number. Flow inside a duct- velocity boundary layer, hydrodynamic entrance length and hydro dynamically developed flow; flow through tubes (internal flow) (discussion only). Numericals based on empirical relation given in data handbook.
Free or Natural Convection:
Application of dimensional analysis for free convection- physical significance of Grashoff number; use of correlations free convection from or to vertical, horizontal and inclined flat plates, vertical and horizontal cylinders and spheres, Numerical problems.
Forced Convections:
Applications of dimensional analysis for forced convection. Physical significance of Reynolds, Prandtl, Nusselt and Stanton numbers. Use of various correlations for hydro dynamically and thermally developed flows inside a duct use of correlations for flow over a flat plate, over a cylinder and sphere. Numericals.

Module 4

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Module 5

Thermal radiation:
Definitions of various terms used in radiation heat transfer; Stefan-Boltzman law, Kirchoff’s law, Planck’s law and Wein’s displacement t law. Radiation heat exchange between two parallel infinite black surfaces, between two parallel infinite gray surfaces; effect of radiation shield; intensity of radiation and solid angle; Lambert’s law; radiation heat exchange between two finite surfaces-configuration factor or view factor. Numerical problems.

Course Outcomes:

After completion of above course, students will be able to

• Demonstrate fundamental principles and laws of conduction, convection and radiation modes of heat transfer.
• Analyze one dimensional steady state heat transfer.
• Analyze one dimensional one dimensional unsteady state heat transfer.
• Analyze one dimensional forced convection heat transfer problems.
• Analyze one dimensional free convection heat transfer problems.
• Analyze one dimensional application like flow over flat plate etc.
• Introduce basic principle of heat exchanger analysis and thermal design.
• Apply laws of radiation heat transfer to solve engineering problems.

Text Books:

1. Heat transfer- P. K. Nag, Tata McGraw Hill 2002.
2. Heat transfer-A basic approach- Ozisik, Tata McGraw Hill 2002.

Reference Books:

1. Heat transfer, a practical approach-Yunus A, Cengel Tata McGraw Hill.
2. Principles of heat transfer – Kreith Thomas Learning 2001.
3. Fundamentals of heat and mass transfer – Frenk P. Incropera and David P. Dewitt, John Wileyand son’s.
4. Heat & Mass transfer- Tirumaleshwar, Pearson education 2006

For detail syllabus of all other subjects of BE Auto, 2017 scheme do visit Auto 6th Sem syllabus for 2017 scheme.

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