MCL106: Difference between revisions
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| credits = 4 | | credits = 4 | ||
| credit_structure = 3-1-0 | | credit_structure = 3-1-0 | ||
| pre_requisites = APL100 | | pre_requisites = [[APL100]] | ||
| overlaps = | | overlaps = | ||
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== MCL106 : Fluid Mechanics == | == MCL106 : Fluid Mechanics == | ||
Overlaps: APL105, APL106, APL107 Introduction: scope, methods of analysis (system vs. volume), Fluid as a continuum, Eulerian/Lagrangian description, Newton's law of viscosity. Fluid Statics: Hydrostatic force on submerged surfaces, Buoyancy and stability, Fluids in rigid-body motion.Flow kinematics: Flow lines, vorticity and circulation. Integral flow analysis: Reynolds transport theorem, conservation or mass, linear and angular momentum for inertial and accelerating control volumes. conservation of energy, Bernoulli's equation. Differential analysis of fluid motion: Conservation of mass. stream function for 2D incompressible flow, fluid translation, rotation and deformation, conservation of momentum, Navier-Stokes equations, incompressible inviscid flows, potential flow. Dimensional analysis and similitude: Dimensionless groups, scaling, non-dimensionalization. Viscous flows: fully developed laminar and turbulent pipe flows, head loss, boundary layer concept, flow separation, comparison of laminar and turbulent velocity profiles, streamlining and implications. Compressible flow: speed of sound, the Mach cone, stagnation properties. critical conditions, isentropic flows and converging-diverging nozzles. | Overlaps: [[APL105]], [[APL106]], [[APL107]] Introduction: scope, methods of analysis (system vs. volume), Fluid as a continuum, Eulerian/Lagrangian description, Newton's law of viscosity. Fluid Statics: Hydrostatic force on submerged surfaces, Buoyancy and stability, Fluids in rigid-body motion.Flow kinematics: Flow lines, vorticity and circulation. Integral flow analysis: Reynolds transport theorem, conservation or mass, linear and angular momentum for inertial and accelerating control volumes. conservation of energy, Bernoulli's equation. Differential analysis of fluid motion: Conservation of mass. stream function for 2D incompressible flow, fluid translation, rotation and deformation, conservation of momentum, Navier-Stokes equations, incompressible inviscid flows, potential flow. Dimensional analysis and similitude: Dimensionless groups, scaling, non-dimensionalization. Viscous flows: fully developed laminar and turbulent pipe flows, head loss, boundary layer concept, flow separation, comparison of laminar and turbulent velocity profiles, streamlining and implications. Compressible flow: speed of sound, the Mach cone, stagnation properties. critical conditions, isentropic flows and converging-diverging nozzles. | ||
Latest revision as of 16:38, 14 April 2026
| MCL106 | |
|---|---|
| Fluid Mechanics | |
| Credits | 4 |
| Structure | 3-1-0 |
| Pre-requisites | APL100 |
| Overlaps | |
MCL106 : Fluid Mechanics
Overlaps: APL105, APL106, APL107 Introduction: scope, methods of analysis (system vs. volume), Fluid as a continuum, Eulerian/Lagrangian description, Newton's law of viscosity. Fluid Statics: Hydrostatic force on submerged surfaces, Buoyancy and stability, Fluids in rigid-body motion.Flow kinematics: Flow lines, vorticity and circulation. Integral flow analysis: Reynolds transport theorem, conservation or mass, linear and angular momentum for inertial and accelerating control volumes. conservation of energy, Bernoulli's equation. Differential analysis of fluid motion: Conservation of mass. stream function for 2D incompressible flow, fluid translation, rotation and deformation, conservation of momentum, Navier-Stokes equations, incompressible inviscid flows, potential flow. Dimensional analysis and similitude: Dimensionless groups, scaling, non-dimensionalization. Viscous flows: fully developed laminar and turbulent pipe flows, head loss, boundary layer concept, flow separation, comparison of laminar and turbulent velocity profiles, streamlining and implications. Compressible flow: speed of sound, the Mach cone, stagnation properties. critical conditions, isentropic flows and converging-diverging nozzles.