Advanced Fluid Mechanics Detailed Syllabus for Thermal Engineering M.Tech first year first sem is covered here. This gives the details about credits, number of hours and other details along with reference books for the course.<\/p>\n
The detailed syllabus for Advanced Fluid Mechanics M.Tech 2017-2018 (R17) first year first sem is as follows.<\/p>\n
M.Tech. I Year I Sem.<\/p>\n
UNIT – I: Inviscid Flow of Incompressible Fluids:<\/strong> Lagrangian and Eulerain Descriptions of fluid motion- Path lines, Stream lines, Streak lines, stream tubes \u2013 velocity of a fluid particle, types of flows – Stream and Velocity potential functions. Basic Laws of fluid Flow: Potential flow, Condition for irrotationality, circulation & vorticity Accelerations in Carte systems normal and tangential accelerations, Euler\u2019s, Bernouli equationsDimensional Analysis & Similarity<\/p>\n UNIT – II: Viscous Flow:<\/strong> Equation of Fluid flow-Continuity & Momentum equation. Derivation of Navier-Stoke\u2019s Equations for viscous compressible flow \u2013 Exact solutions to certain simple cases : Plain Poisoulle flow – Coutte flow with and without pressure gradient – Hagen Poisoulle flow.<\/p>\n UNIT III: Boundary Layer Concepts :<\/strong> External Flow-Prandtl\u2019s contribution to real fluid flows \u2013Blasius solution-Prandtl\u2019s boundary layer theory – Boundary layer thickness for flow over a flat plate \u2013 Approximate solutions \u2013 Creeping motion (Stokes) \u2013 Oseen\u2019s approximation – Von-Karman momentum integral equation for laminar boundary layer \u2013\u2013 Expressions for local and mean drag coefficients for different velocity profiles for flow over flat plates-Flow over Blunt objects-Boundary layer development-Drag calculation.<\/p>\n UNIT IV: Internal Flow:<\/strong> Boundary layer development-Hydrodynamic entry length-Smooth and rough boundaries \u2013 Equations for Velocity Distribution and frictional Resistance in smooth rough Pipes \u2013 Roughness of Commercial Pipes \u2013 Moody\u2019s diagram. Introduction to Turbulent Flow: Fundamental concept of turbulence \u2013 Time Averaged Equations \u2013 Boundary Layer Equations – Prandtl Mixing Length Model – Universal Velocity Distribution Law: Van Driest Model \u2013Approximate solutions for drag coefficients \u2013 More Refined Turbulence Models \u2013 kepsilon model.<\/p>\n UNIT V: Compressible Fluid Flow \u2013 I:<\/strong> Thermodynamic basics \u2013 Sonic Velocity \u2013 Mach Number – Generalized and simple 1D compressible flows – Development of Equations – Acoustic Velocity Derivation of Equation for Mach Number \u2013 Area \u2013 Pressure Velocity Relationship Compressible Fluid Flow \u2013 II: Nozzles, Diffusers \u2013 Isothermal Flow in Long Ducts – Fanno and Releigh Lines, Property Relations \u2013\u2013 Normal Compressible Shock, Oblique Shock: Expansion and Compressible Shocks \u2013 Supersonic Wave Drag<\/p>\n REFERENCES:<\/strong><\/p>\n\n