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MAE 5350: Gas Turbines

Learn about the kinematic properties, differential and integral forms, and applications of mass and momentum equations in gas turbines and rocket engines. Understand control volume analyses, Newton's 2nd Law, rocket propulsion, thermal energy, and thrust definitions.

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MAE 5350: Gas Turbines

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  1. MAE 5350: Gas Turbines Integral Forms of Mass and Momentum Equations Mechanical and Aerospace Engineering Department Florida Institute of Technology D. R. Kirk

  2. Kinematic Properties: Two ‘Views’ of Motion • Lagrangian Description • Follow individual particle trajectories • Choice in solid mechanics • Control mass analyses • Mass, momentum, and energy usually formulated for particles or systems of fixed identity • ex., F=d/dt(mV) is Lagrangian in nature • Eulerian Description • Study field as a function of position and time; not follow any specific particle paths • Usually choice in fluid mechanics • Control volume analyses • Eulerian velocity vector field: • Knowing scalars u, v, w as f(x,y,z,t) is a solution

  3. CONSERVATION OF MASS • This is a single scalar equation • Velocity doted with normal unit vector results in a scalar • 1st Term: Rate of change of mass inside CV • If steady d/dt( ) = 0 • Velocity, density, etc. at any point in space do not change with time, but may vary from point to point • 2nd Term: Rate of convection of mass into and out of CV through bounding surface, S • 3rd Term (=0): Production or source terms Relative to CS Inertial

  4. Integral vs. Differential Form • Integral form of mass conservation • Apply Divergence (Gauss’) Theorem • Transform both terms to volume integrals • Results in continuity equation in the form of a partial differential equation • Applies to a fixed point in the flow • Only assumption is that fluid is a continuum • Steady vs. unsteady • Viscous vs. inviscid • Compressible vs. incompressible

  5. Summary: Incompressible vs. Constant Density • Two equivalent statements of conservation of mass in differential form • In an incompressible flow • Says particles are constant volume, but not necessarily constant shape • Density of a fluid particle does not change as it moves through the flow field • Incompressible: Density may change within the flow field but may not change along a particle path • Constant Density: Density is the same everywhere in the flow field

  6. MOMENTUM EQUATION: NEWTONS 2nd LAW Inertial Relative to CS • This is a vector equation in 3 directions • 1st Term: Rate of change of momentum inside CV or Total (vector sum) of the momentum of all parts of the CV at any one instant of time • If steady d/dt( ) = 0 • Velocity, density, etc. at any point in space do not change with time, but may vary from point to point • 2nd Term: Rate of convection of momentum into and out of CV through bounding surface, S or Net rate of flow of momentum out of the control surface (outflow minus inflow) • 3rd Term: • Notice that sign on pressure, pressure always acts inward • Shear stress tensor, t, drag • Body forces, gravity, are volumetric phenomena • External forces, for example reaction force on an engine test stand • Application of a set of forces to a control volume has two possible consequences • Changing the total momentum instantaneously contained within the control volume, and/or • Changing the net flow rate of momentum leaving the control volume

  7. Application to Rocket Engines F Chemical Energy Rocket Propulsion (class of jet propulsion) that produces thrust by ejecting stored matter • Propellants are combined in a combustion chamber where chemically react to form high T&P gases • Gases accelerated and ejected at high velocity through nozzle, imparting momentum to engine • Thrust force of rocket motor is reaction experienced by structure due to ejection of high velocity matter • Same phenomenon which pushes a garden hose backward as water flows from nozzle, gun recoil Thermal Energy Kinetic Energy

  8. Application to Airbreathing Engines Chemical Energy Kinetic Energy Thermal Energy • Flow through engine is conventionally called THRUST • Composed of net change in momentum of inlet and exit air • Fluid that passes around engine is conventionally called DRAG

  9. Thrust Definitions • Use of conservation of mass and momentum in control volume form to derive governing equation for “net uninstalled thrust” • See Section 3.1 • Textbook notation: Fn)uninstalled • Pay close attention to control volume choices • Control volume option 1: pages 113 – 119 • Control volume option 2: pages 121 - 124 • Understand each term, including the ram drag and pressure mismatch • Can divide into nozzle contribution and inlet contribution • Nozzle contribution is called “gross thrust” • Textbook notation: Fg • Uninstalled Thrust: thrust produced by engine if it had zero external losses • Installed Thrust: actual propulsive force transmitted to aircraft by engine

  10. Efficiency Summary • Overall Efficiency • What you get / What you pay for • Propulsive Power / Fuel Power • Propulsive Power = TUo • Fuel Power = (fuel mass flow rate) x (fuel energy per unit mass) • Thermal Efficiency • Rate of production of propulsive kinetic energy / fuel power • This is cycle efficiency • Propulsive Efficiency • Propulsive Power / Rate of production of propulsive kinetic energy, or • Power to airplane / Power in Jet

  11. MOMENTUM EQUATION: NEWTONS 2nd LAW Relative to CS Inertial • This is a vector equation in 3 directions • 1st Term: Rate of change of momentum inside CV or Total (vector sum) of the momentum of all parts of the CV at any one instant of time • If steady d/dt( ) = 0 • Velocity, density, etc. at any point in space do not change with time, but may vary from point to point • 2nd Term: Rate of convection of momentum into and out of CV through bounding surface, S or Net rate of flow of momentum out of the control surface (outflow minus inflow) • 3rd Term: • Notice that sign on pressure, pressure always acts inward • Shear stress tensor, t, drag • Body forces, gravity, are volumetric phenomena • External forces, for example reaction force on an engine test stand • Application of a set of forces to a control volume has two possible consequences • Changing the total momentum instantaneously contained within the control volume, and/or • Changing the net flow rate of momentum leaving the control volume

  12. Momentum Equation: Mid-Air Refueling • An F-4 Phantom is being refueled in mid-air • Refueling boom enters at an angle of 30° from the F-4 flight path • Fuel flow rate through the boom is 20 kg/s at a velocity of 30 m/s relative to the two aircraft • Density of jet fuel is less than water, and is about 700 kg/m3 • What additional lift force is necessary to overcome force on F-4 fighter due to momentum transfer during refueling?

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