Sl. No

Course Code

Course Name

L-T-P-C

1

ME501

Advanced Engineering Mathematics

3-0-2-8

2

ME 520

Fluid Mechanics

3-0-0-6

3

ME 523

Advanced Thermodynamics 

3-0-0-6

4

ME XXX

Elective -I

3-0-0-6

5

ME XXX

Elective -II

3-0-0-6

Total

15-0-2-32

Sl. No

Course Code

Course Name

L-T-P-C

1

ME 522

Convective Heat and Mass Transfer

3-0-0-6

2

ME XXX

Elective -III

3-0-0-6

3

ME XXX

Elective -IV

3-0-0-6

4

ME XXX

Elective -V

3-0-0-6

5

ME XXX

Elective -VI

3-0-0-6

Total

15-0-0-30

Sl. No

Course Code

Course Name

L-T-P-C

1

ME 610

Project Phase 1

0-0-24-24

Sl. No

Course Code

Course Name

L-T-P-C

1

ME 690

Project phase II

0-0-24-24

ME 501             Advanced Engineering Mathematics   (3-0-2-8)            

Vector and Tensor Analysis in Cartesian system, effect of rotation of coordinate systems.

Review of ODEs; Laplace & Fourier methods, series solutions, and orthogonal polynomials.  Sturm-Liouville problem. Review of 1^st and 2^nd order PDEs.  Linear systems of algebraic equations. Gauss elimination, LU decomposition etc., Matrix inversion, ill-conditioned systems.  Numerical eigen solution techniques (Power,   Householder, QR methods etc.). Numerical solution of systems of nonlinear algebraic equations; Newton-Raphson method.  Numerical integration: Newton-Cotes methods, error estimates, Gaussian quadrature. Numerical solution of ODEs: Euler, Adams, Runge-Kutta methods, and predictor-corrector procedures; stability of solutions; solution of stiff equations.  Solution of PDEs: finite difference techniques. Probability and Statistics – Probability Distribution, Bays Theorem, Parameter Estimation, Testing of Hypothesis, Goodness of Fit.

Laboratory: Basics of programming. Numerical experiments with the algorithms covered in class.

Texts/References:

1.       E. Kreyzig, Advanced Engineering Mathematics, New Age International, 1996.

2.       D. S. Watkins, Fundamentals of Matrix Computations, John Wiley, 1992.

3.       M. K. Jain, S. R. K. Iyengar, and R. K. Jain, Numerical Methods for Scientific and

        Engineering Computation, 3^rd Ed., New Age International, 1993.

4.       D.S. Chandrashekaraiah and L. Debnath, Continuum Mechanics, Academic Press, 1994.

5.     M.K. Jain, S.R.K. Iyenger and R.K. Jain, Computational Methods for Partial Differential Equations, New Age International, 1994.

6.       R. Courant and D. Hilbert, Methods of Mathematical Physics, Wiley, 1989.

7.       P.V. O’Neil, Advanced Engineering Mathematics, Cengage Learning, 2007.

8.       4. George B. Arfken, G. B. Arfken, H. J. Weber and F.Harris, Mathematical Methods for Physicists, 5^th Ed., Academic Press, 2000.

ME 520                                     Fluid Mechanics                                                           (3 0 0 6)

Fluid kinematics; Integral and differential forms of governing equations; Mass, momentum, and energy conservation equations; Navier-Stokes equations and its applications; Potential flow; Laminar boundary-layer; Free-shear flows: jet, wake, and mixing layer; Instability and transition; Turbulent flow; Compressible flow: Isentropic flow; flow with area change; flow with heat transfer; flow with friction.

Texts:

1.     B.R.Munson, D.F.Young and T.H.Okiishi., Fundamental of Fluid Mechanics, John Wiley and Sons., 1994.

2.     P.M.Gerhar, R.J.Gross and J.I.Hochstein., Fundamentals of Fluid Mechanics, Addison-Wesley Publishing Co., 1993

3.     H.Schlichting, Boundary Layer Theory, McGraw-Hill Series in Mechanical Engineering, 1979

4.     F.M.White, Fluid Mechanics, McGraw-Hill international editions., 1994.

5.     F.M.White, Viscous Fluid Flow, McGraw-Hill international editions., 1991

ME 522                                     Convective Heat and Mass Transfer                               (3 0 0 6)

Conservation equations and boundary conditions; One-dimensional solutions; Heat transfer in laminar developed and developing duct flows; Laminar boundary layers: Similarity and integral solutions; Turbulence fundamentals and modeling; Heat tranfer in turbulent boundary layers and turbulent duct flows; Laminar and turbulent free convection; Fundamentals of boiling and condensation; Numerical methods.

Texts:

1. W. M. Kays and E. M. Crawford, Convective Heat and Mass Transfer, Mc Graw Hill,1993.

2. Louis C Burmeister, Convective Heat Transfer, John Wiley and Sons, 1993.

3. Adrian Bejan, Convective Heat Transfer, John Wiley and Sons, 1995.

ME 523                                     Advanced Engineering Thermodynamics                          (3 0 0 6)

Review of fist and second law of thermodynamics, Maxwell equations, Joule-Thompson experiment, irreversibility and availability, exergy analysis, phase transition, types of equilibrium and stability, multi-component and multi-phase systems, equations of state, chemical thermodynamics, combustion.  Third law of thermodynamics

Kinetic theory of gases- introduction, basic assumption, molecular flux, equation of state for an ideal gas, collisions with a moving wall, principle of equipartition of energy, classical theory of specific heat capacity.

Transport phenomena-intermolecular forces, The Van der Waals equation of state, collision cross section, mean free path

Statistical thermodynamics- introduction, energy states and energy levels, macro and microscales, thermodynamic probability, B-E, F-D, M-D statistics, distribution function, partition energy, statistical interpretation of entropy, application of statistics to gases-mono-atomic ideal gas, distribution of molecular velocity, ideal gas in a gravitational field.

References:

1. F.W.Sears and G.L.Salinger, Thermodynamics, Kinetic Theory And Statistical Thermodynamics, Narosa Publishing House, New Delhi.

2. Wylen and Sontag, Fundamentals of Classical Thermodynamics, Wiley Eastern Limited, New Delhi.

3. M.J.Moran and H.N.Shapiro, Fundamentals Of Engineering Thermodynamics, John Wiley and Sons.

4. Zemansky, Engineering Thermodynamics, Mc Graw Hill.

5. Bejan, Advanced Engineering Thermodynamics, John Wiley and sons.