Hypersonic flow and flight

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University of Stuttgart, Aerospace Engineering and Geodesy Dept. - Lecture - Hypersonic flow and flight Master Level, Specialization 4 lecture hours per week in WS, 3-6 LPs/ECTS Lecturer: Dr. Markus J. Kloker

NASP Study (USA, 1986) X-43 (USA, 2005) Shuttle (USA, 1981) When which body shape and why? Sänger-Studie (GER) 1963/88

Contents (1) 0 Motivation, own research work (transition, film cooling) I Inviscid I.1 Velociy-altitude map I.2 Shock relations, Tsien s similarity parameter I.3 Expansion wave relations I.4 Waverider principle I.5 Dynamic pressure, total pressure, pressure coefficient, total-pressure loss: definitions and flow-physical meaning in hypersonics I.6 Methods to gain c p based on local surface inclination I.6.1 Newtonian theory I.6.2 Modified Newtonian theory: inclined plate, sphere I.6.3 Methods for sharp bodies only: tangent wedge/cone, shock-expansion I.7 Mach-number independence and similarity for slender bodies I.8 Small-disturbance-theory application: pointed slender circular cone I.9 Conical flow: pointed circular cone, Taylor-Maccoll equation, 3D effects, elliptic cone I.10 Fundamental aspects of flow-field computations - shock fitting/capturing I.10.1 Space-marching techniques, subsonics problem I.10.2 Time-marching: steady/unsteady flow

Contents (2) I.11 Shock standoff distance I.12 Aspects of inviscid/viscous CFD results and the Hyper-X(-43) project II II.1 II.1.1 II.1.2 II.1.2.1 II.1.2.2 II.1.2.3 II.1.3 II.1.3.1 II.1.3.2 Viscous Boundary layers: Navier-Stokes equations and friction terms, parabolized equations volumetric viscosity / second viscosity / thermal relaxation experimental simulation: problems of kinematical inversion Laminar boundary layers and boundary-layer equations Self-similar solutions Flat plate velocity /temperature profile, recovery-temperature, friction /heat coefficient (stanton number), Reynolds analogy Pointed circular cone Stagnation flow: inkompressible case revisited; body shape and boundary-layer state: wall heating Turbulent boundary layers Flat plate: velocity profiles, scaling (van Driest) recovery temperature, wall heating Pointed circular cone

Contents (3) II.1.4 The reference-temperature concept II.2 Laminar-Turbulent Transition II.2.1 Fundamental scenarios: regular, bypass, transient growth; receptivity II.2.2 Linear Stability Theory: disturbance amplification, Mach number influence, vorticity (1 st ) mode and acoustic (2 nd ) mode, supersonic disturbance II.2.3 Transition Prediction: e-to-the-n method (smooth wall); simplified methods (rough wall) II.2.4 wall-cooling, radiation adiabatic wall (radiative equilibrium) II.2.5 Effects of other parameters II.3 Viscous Interaction (boundary-layer/external flow ) II.3.1 pressure interaction near leading edge II.3.2 shock/boundary-layer interaction, front spike III III.1 III.2 High-Temperature Effects gas models: vibrational excitation, dissociation; related velocity-altitude map for earth atmosphere Thermochemical States: equilibrium, frozen flow, non-equilibrium, Damköhler number,

Contents (4) III.2.1 III.2.1.1 III.2.1.2 III.2.1.3 III.2.1.4 III.2.2 III.2.2.1 III.2.2.2 III.2.2.3 III.2.3 III.2.3.1 III.3 Inviscid flow in equilibrium thermodynamics: molecules degrees of freedom chemistry: dissociation-/recombination reactions speed of sound= f (temperature, pressure) Normal shock: reduction of temperature rise Blunt body: reduction of shock stand-off distance Oblique shock: larger maximum deflection angle Nozzle flow: temperature rise by reombinations Inviscid flow in non-equilibrium Nozzle flow: thermochemically, thermally frozen Normal shock: route from frozen state to equilibrium Blunt body: regions of iso-thermochemical states Viscous flow: diffusion; wall heat flux dependent on wall catalycity Stagnation flow: boundary-layer profiles and wall heat flux = f (reaction rates in the boundary layer with binary gas) Aspects of the SHEFEX project (facetted forebody nose)

Contents (5) Basic literature [1] John D. Anderson Jr.: Hypersonic and High-Temperature Gas Dynamics. AIAA, 2006, 2 nd edition (McGraw-Hill, 1989), ISBN 1-56347-780-7 (ca. 95) [2] Ernst H. Hirschel: Basics of Aerothermodynamics. Springer, 2004, ISBN 3-540-22132-8 (ca. 65/95) [3] Johann T. Heynatz: Hyperschallströmungen Grundlagen und Hinweise. Verlag Dieter Thomas, 1997, ISBN 3-931776-11-5 (ca. 34) [4] John D. Anderson Jr.: Modern Compressible Flow. McGraw-Hill, 3 rd ed. 2004, ISBN 978-0071241366 ( 60-220). [5] Maurice Rasmussen:. Wiley Interscience, 1994, ISBN 0-471-51102-1 ( 185) [6] Frank M. White: Viscous Fluid Flow. McGraw-Hill, 3 rd ed. 2005, ISBN 978-0071244930 ( 60-220) [7] Hermann Schlichting, Klaus Gersten: Boundary-Layer Theory. Springer, 8 th ed. 2003, ISBN 3-540-66270-7 (or: previous eds. McGraw-Hill)

Newtonian Theory for inviscid c p, c D, c L local surface area modified Newtonian: 0.92 M >>1 c D Locally: c p =c ps sin 2 - Newtonian: c ps = 2 - modif. Newt. c ps = 1.84 (air) (> 1!) M Fig. Drag coefficient for a sphere and cylinder with conical forebody as a function of Mach number (symbols: flight experiments) [1]. Mach number independence starts earlier for blunt bodies because of larger shock angles. c D (sphere, M =0) is for 10 3 Re D 10 5 (laminar separation).

Laminar-turbulent Transition (5) a) b) T W /T 0 2500 [K] 2000 T W 1500 1000 T trans, max > T turb 500 0 0.1 0.5 x/l 1.0 V Fig. Temperature along laminar-turbulent transition a) pointed circular cone with flare, M=6, R nose =2.5μm [Horvath et. al, RTO-RSM-AVT-111, Prag, 2004]. b) symmetry line for Sänger lower stage, Re unit =1.5 10 6 /m, L V =55m, M=6.8, =6 at adiabatic (ε=0) and radiation-adiabatic (cooled, ε=0.85) wall; steady CFD with transition position fixed [2]). With radiative equilibrium the temperature increase is strong. During transition the turbulent value is often surpassed.

Viscous interaction (1) Fig. a Effect of an aerospike. 1 front shock by spike, 2 recirculation region, 3 separation shock, 4 re-attachment shock. Density, Mach 7, thesis by Gauer, HyShot-IAG, 2006 (2-d axisymmetric CFD).

Viscous interaction (2) Fig. b Aerospike with L/D=2, D/d=4, density- and axial velocity at M=7. L spike length, D nose diameter of main body, d of forebody; drag reduction: 46%.

Viscous interaction (3) Fig. c Like fig. b, temperature distribution (upper) and u-isolines in the recirculation region (lower); middle: perspective view.

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