Advanced propulsion systems (3 lectures)

1. Advanced propulsion systems (3 lectures) • Hypersonic propulsion background (Lecture 1) • Why hypersonic propulsion? • What’s different at hypersonic conditions? • Real gas effects (non-constant CP, dissociation) • Aircraft range • How to compute thrust? • Idealized compressible flow (Lecture 2) • Isentropic, shock, friction (Fanno) • Heat addition at constant area (Rayleigh), T, P • Hypersonic propulsion applications (Lecture 3) • Ramjet/scramjets • Pulse detonation engines • Combustion instability (Lecture 3) AME 514 - Spring 2013 - Lecture 10

2. Why use air even if you’re going to space? • Carry only fuel, not fuel + O2, while in atmosphere • 8x mass savings (H2-O2), 4x (hydrocarbons) • Actually even more than this when the ln( ) term in the Breguet range equation is considered • Use aerodynamic lifting body rather than ballistic trajectory • Ballistic: need Thrust/weight > 1 • Lifting body, steady flight: Lift (L) = weight (mg); Thrust (T) = Drag (D), Thrust/weight = L/D > 1 for any decent airfoil, even at hypersonic conditions L T D mg AME 514 - Spring 2013 - Lecture 10

3. What’s different about hypersonic propulsion? • Stagnation temperature Tt - measure of total energy (thermal + kinetic) of flow - is really large even before heat addition - materials problems • T = static temperature- T measured by a thermometer moving with the flow • Tt = temperature of the gas if it is decelerated adiabatically to M = 0 •  = gas specific heat ratio = Cp/Cv; M = Mach number = u/(RT)1/2 • Stagnation pressure - measure of usefulness of flow (ability to expand flow) is really large even before heat addition - structural problems • P = static pressure - P measured by a pressure gauge moving with the flow • Pt = pressure of the gas if it is decelerated reversibly and adiabatically to M = 0 • Large Pt means no mechanical compressor needed at large M AME 514 - Spring 2013 - Lecture 10

4. What’s different about hypersonic propulsion? • Why are Tt and Pt so important? Isentropic expansion until exit pressure (P9) = ambient pressure (P1) (optimal exit pressure yielding maximum thrust) yields • … but it’s difficult to add heat at high M without major loss of stagnation pressure AME 514 - Spring 2013 - Lecture 10

5. What’s different about hypersonic propulsion? • High temperatures:  not constant, also molecular weight not constant - dissociation - use GASEQ (http://www.gaseq.co.uk) to compute stagnation conditions • Example calculation: standard atmosphere at 100,000 ft • T1 = 227K, P1 = 0.0108 atm, c1 = 302.7 m/s, h1 = 70.79 kJ/kg (atmospheric data from http://www.digitaldutch.com/atmoscalc/) • Pick P2 > P1, compress isentropically, note new T2 and h2 • 1st Law: h1 + u12/2 = h2 + u22/2; since u2 = 0, h2 = h1 + (M1c1)2/2 or M1 = [2(h2-h1)/c12]1/2 • Simple relations ok up to M ≈ 7 • Dissociation not as bad as might otherwise be expected at ultra high T, since P increases faster than T • Problems • Ionization not considered • Stagnation temperature relation valid even if shocks, friction, etc. (only depends on 1st law) but stagnation pressure assumes isentropic flow • Calculation assumed adiabatic deceleration - radiative loss (from surfaces and ions in gas) may be important AME 514 - Spring 2013 - Lecture 10

6. WOW!HOTWARMCOLD 5000K3000K1000K200K N+O+e-N2+ON2+O2N2+O2 What’s different about hypersonic propulsion? AME 514 - Spring 2013 - Lecture 10

7. Thrust computation • In airbreathing and rocket propulsion we need THRUST (force acting on vehicle) • How much push can we get from a given amount of fuel? • We’ll start by showing that thrust depends primarily on the difference between the engine inlet and exhaust gas velocity, then compute exhaust velocity for various types of flows (isentropic, with heat addition, with friction, etc.) AME 514 - Spring 2013 - Lecture 10

8. Thrust computation • Control volume for thrust computation - in frame of reference moving with the engine AME 514 - Spring 2013 - Lecture 10

9. Thrust computation - steady flight • Newton’s 2nd law: Force = rate of change of momentum • At takeoff u1 = 0; for rocket no inlet so u1 = 0 always • For hydrogen or hydrocarbon-air FAR << 1; typically 0.06 at stoichiometric AME 514 - Spring 2013 - Lecture 10

10. Thrust computation • But how to compute exit velocity (u9) and exit pressure (P9) as a function of ambient pressure (P1), flight velocity (u1)? Need compressible flow analysis, next lecture … • And you can obtain a given thrust with small [(1+FAR)u9 - u1] and large large (P9 – P1)A9 or vice versa - which is better, i.e. for given , u1, P1 and FAR, what P9 will give most thrust? Differentiate thrust equation and set = 0 • Momentum balance on exit (see next slide) • Combine  Optimal performance occurs for exit pressure = ambient pressure AME 514 - Spring 2013 - Lecture 10

11. 1D momentum balance - constant-area duct Coefficient of friction (Cf) AME 514 - Spring 2013 - Lecture 10

12. Thrust computation • But wait - this just says P9 = P1 is an extremum - is it a minimum or a maximum? but Pe = Pa at the extremum cases so • Maximum thrust if d2(Thrust)/d(P9)2 < 0  dA9/dP9 < 0 - we will show this is true for supersonic exit conditions • Minimum thrust if d2(Thrust)/d(P9)2 > 0  dA9/dP9 > 0 - we will show this is would be true for subsonic exit conditions, but for subsonic, P9 = P1 always since acoustic (pressure) waves can travel up the nozzle, equalizing the pressure to P9, so it’s a moot point for subsonic exit velocities AME 514 - Spring 2013 - Lecture 10

13. Propulsive, thermal, overall efficiency • Thermal efficiency (th) • Propulsive efficiency (p) • Overall efficiency (o) this is the most important efficiency in determining aircraft performance (see Breguet range equation, coming up…) AME 514 - Spring 2013 - Lecture 10

14. Propulsive, thermal, overall efficiency • Note on propulsive efficiency for FAR << 1 • p  1 as u1/u9  1  u9 is only slightly larger than u1 • But then you need large to get required Thrust ~ (u9 - u1); but this is how commercial turbofan engines work! • In other words, the best propulsion system accelerates an infinite mass of air by an infinitesimal u • Fundamentally this is because Thrust ~ (u9 - u1), but energy required to get that thrust ~ (u92 - u12)/2 • For hypersonic propulsion systems, u1 is large, u9 - u1 << u1, so propulsive efficiency usually high (i.e. close to 1) AME 514 - Spring 2013 - Lecture 10

15. Specific Thrust • Specific thrust – thrust per unit mass flow rate, non-dimensionalizedby sound speed at ambient conditions (c1) For any 1D steady propulsion system For any 1D steady propulsion system if working fluid is an ideal gas with constant CP,  AME 514 - Spring 2013 - Lecture 10

16. Specific Thrust • Specific thrust (ST) continued…if P9 = P1 and FAR << 1 then • Thrust Specific Fuel Consumption (TSFC) (PDR’s definition) • Usual definition of TSFC is just , but this is not dimensionless; use QR to convert to heat input, one can use either u1 or c1 to convert the denominator to a quantity with units of power, but using u1 will make TSFC blow up at u1 = 0 • Specific impulse(Isp) = thrust per weight (on earth) flow rate of fuel (+ oxidant if two reactants carried, e.g. rocket) (units of seconds) AME 514 - Spring 2013 - Lecture 10

17. Breguet range equation • Consider aircraft in level flight (Lift = weight) at constant flight velocity u1 (thrust = drag) • Combine expressions for lift & drag and integrate from time t = 0 to t = R/u1 (R = range = distance traveled), i.e. time required to reach destination, to obtainBreguet Range Equation Lift (L) Thrust Drag (D) Weight (W = mvehicleg) AME 514 - Spring 2013 - Lecture 10

18. Rocket equation • If acceleration (u) rather than range in steady flight is desired [neglecting drag (D) and gravitational pull (W)], Force = mass x acceleration or Thrust = mvehicledu/dt • Since flight velocity u1 is not constant, overall efficiency is not an appropriate performance parameter; instead use specific impulse (Isp) = thrust per unit weight (on earth) flow rate of fuel (+ oxidant if two reactants carried), i.e. Thrust = mdotfuel*gearth*Isp • Integrate to obtainRocket Equation • Of course gravity and atmospheric drag will increase effective u requirement beyond that required strictly by orbital mechanics AME 514 - Spring 2013 - Lecture 10

19. Breguet& rocket equations - comments • Range (R) for aircraft depends on • o (propulsion system) - depends on u1 for airbreathing propulsion • QR (fuel) • L/D (lift to drag ratio of airframe) • g (gravity) • Fuel consumption (minitial/mfinal); minitial - mfinal = fuel mass used (or fuel + oxidizer, if not airbreathing) • This range does not consider fuel needed for taxi, takeoff, climb, decent, landing, fuel reserve, etc. • Note (irritating) ln( ) or exp( ) term in both Breguet and Rocket: because you have to use more fuel at the beginning of the flight, since you’re carrying fuel you won’t use until the end of the flight - if not for this it would be easy to fly around the world without refueling and the Chinese would have sent skyrockets into orbit thousands of years ago! AME 514 - Spring 2013 - Lecture 10

20. Breguet& rocket equations - examples • Fly around the world (g = 9.8 m/s2) without refueling • R = 40,000 km • Use hydrocarbon fuel (QR = 4.5 x 107 J/kg), • Good propulsion system (o = 0.25) • Good airframe (L/D = 20), • Need minitial/mfinal ≈ 5.7 - aircraft has to be mostly fuel - mfuel/minitial= (minitial - mfinal)/minitial = 1 - mfinal/minitial = 1 - 1/5.7 = 0.825! - that’s why no one flew around with world without refueling until 1986 • To get into orbit from the earth’s surface • u = 8000 m/s • Use a good rocket propulsion system (e.g. Space Shuttle main engines, ISP ≈ 400 sec) • Need minitial/mfinal ≈ 7.7 can’t get this good a mass ratio in a single vehicle - need staging - that’s why no one put an object into earth orbit until 1957 AME 514 - Spring 2013 - Lecture 10