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A three-dimensional upwind parabolized Navier-Stokes code for chemically reacting flows (1990)

Tannehill, John C. ; Buelow, Philip E. ; Ievalts, John O. ; [et al.]

In: Other Sources

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Publication Date: 2019-06-28

Description: A new upwind, parabolized Navier-Stokes (PNS) code has been developed to compute the three-dimensional flow of chemically reacting air around hypersonic vehicles. The code is a modification of the perfect gas, three-dimensional UPS code of Lawrence et al. (1986) which has been extended in the present study to permit the calculation of hypersonic, viscous flows in chemical nonequilibrium. The algorithm solves the PNS equations using a finite-volume, upwind TVD method based on Roe's approximate Riemann solver that has been modified to account for real gas effects. The present code solves the fluid dynamic and species continuity equations in a loosely-coupled manner. The fluid medium is assumed to be a chemically reacting mixture of thermally perfect (but calorically imperfect) gases in thermal equilibrium. Results are presented for the hypersonic laminar flow over a cone at 0- and 10-deg angles of attack and for a generic hypersonic vehicle. Calculations are performed assuming either perfect gas, equilibrium air, or finite-rate chemistry.

Keywords: AERODYNAMICS

Type: AIAA PAPER 90-0394

Format: text

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2

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Current status of computational methods for transonic unsteady aerodynamics and aeroelastic applications (1992)

Malone, John B. ; Edwards, John W.

In: CASI

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Publication Date: 2017-10-02

Description: The status of computational methods for unsteady aerodynamics and aeroelasticity is reviewed. The key features of challenging aeroelastic applications is discussed in terms of the flowfield state - low angle high speed flows and high angle vortex dominated flows. The critical role played by viscous effects in determining aeroelastic stability for conditions of incipient flow separation is stressed. The need for a variety of flow modeling tools, from linear formulations to implementations of the Navier-Stokes equations, is emphasized. Estimates of computer run times for flutter calculations using several computational methods are given. Applications of these methods for unsteady aerodynamic and transonic flutter calculations for airfoils, wings, and configurations are summarized. Finally, recommendations are made concerning future research directions.

Keywords: AERODYNAMICS

Type: AGARD, Transonic Unsteady Aerodynamics and Aeroelasticity; 24 p

Format: text

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3

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Reynolds number influences in aeronautics (1993)

Yip, Long P. ; Domack, Christopher S. ; Hardin, Jay C. ; [et al.]

In: CASI

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Publication Date: 2019-06-28

Description: Reynolds number, a measure of the ratio of inertia to viscous forces, is a fundamental similarity parameter for fluid flows and therefore, would be expected to have a major influence in aerodynamics and aeronautics. Reynolds number influences are generally large, but monatomic, for attached laminar (continuum) flow; however, laminar flows are easily separated, inducing even stronger, non-monatomic, Reynolds number sensitivities. Probably the strongest Reynolds number influences occur in connection with transitional flow behavior. Transition can take place over a tremendous Reynolds number range, from the order of 20 x 10(exp 3) for 2-D free shear layers up to the order of 100 x 10(exp 6) for hypersonic boundary layers. This variability in transition behavior is especially important for complex configurations where various vehicle and flow field elements can undergo transition at various Reynolds numbers, causing often surprising changes in aerodynamics characteristics over wide ranges in Reynolds number. This is further compounded by the vast parameterization associated with transition, in that any parameter which influences mean viscous flow development (e.g., pressure gradient, flow curvature, wall temperature, Mach number, sweep, roughness, flow chemistry, shock interactions, etc.), and incident disturbance fields (acoustics, vorticity, particulates, temperature spottiness, even electro static discharges) can alter transition locations to first order. The usual method of dealing with the transition problem is to trip the flow in the generally lower Reynolds number wind tunnel to simulate the flight turbulent behavior. However, this is not wholly satisfactory as it results in incorrectly scaled viscous region thicknesses and cannot be utilized at all for applications such as turbine blades and helicopter rotors, nacelles, leading edge and nose regions, and High Altitude Long Endurance and hypersonic airbreathers where the transitional flow is an innately critical portion of the problem.

Keywords: AERODYNAMICS

Type: NASA-TM-107730 , NAS 1.15:107730

Format: application/pdf

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4

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An upwind parabolized Navier-Stokes code for chemically reacting flows (1988)

Ievalts, John O. ; Tannehill, John C. ; Lawrence, Scott L. ; [et al.]

In: Other Sources

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Publication Date: 2019-06-28

Description: A new upwind, parabolized Navier-Stokes (PNS) code has been developed to compute the hypersonic, viscous, chemically reacting flow around two-dimensional or axisymmetric bodies. The new code is an extension of the upwind (perfect gas) PNS code of Lawrence et al. (1986). The upwind algorithm is based on Roe's flux-difference splitting scheme which has been modified to account for real gas effects. The algorithm solves the gas dynamic and species continuity equations in a 'loosely' coupled manner. The new code has been validated by computing the laminar flow (at free stream Mach number 25) of chemically reacting air over a wedge and a cone. The results of these computations are compared with the results from a centrally-differenced, fully coupled, nonequilibrium PNS code. The agreement is excellent, except in the vicinity of the shock wave where the present code exhibits superior shock capturing capabilities.

Keywords: AERODYNAMICS

Type: AIAA PAPER 88-2614

Format: text

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5

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Comparison of three-dimensional nonequilibrium PNS codes (1990)

Buelow, Philip E. ; Ievalts, John O. ; Tannehill, John C.

In: Other Sources

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Publication Date: 2019-06-28

Description: A comparison study has been conducted using four recently developed parabolized Navier-Stokes (PNS) codes which have the capability of predicting finite-rate, chemically reacting flows over three-dimensional bodies. These are the (1) UPS code, (2) the STUFF code, (3) the TONIC code, and (4) the VRA-PNS code. All of the codes use the same seven-species, single-temperature air chemistry model, but otherwise they are unique, with different capabilities and characteristics. The differences include upwinding vs central differencing, strongly-coupled vs weakly-coupled chemistry, shock capturing vs shock fitting, finite volume vs finite difference, and full PNS vs thin-layer PNS equations. Three test cases were utilized to compare the codes. The comparisons presented indicate a good agreement among the codes tested.

Keywords: AERODYNAMICS

Type: AIAA PAPER 90-1572

Format: text

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6

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X-29 flight control system: Lessons learned (1994)

Bosworth, John T. ; Bauer, Jeffery E. ; Burken, John J. ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: Two X-29A aircraft were flown at the NASA Dryden Flight Research Center over a period of eight years. The airplanes' unique features are the forward-swept wing, variable incidence close-coupled canard and highly relaxed longitudinal static stability (up to 35-percent negative static margin at subsonic conditions). This paper describes the primary flight control system and significant modifications made to this system, flight test techniques used during envelope expansion, and results for the low- and high-angle-of-attack programs. Through out the paper, lessons learned will be discussed to illustrate the problems associated with the implementation of complex flight control systems.

Keywords: AERODYNAMICS

Type: NASA-TM-4598 , H-1995 , NAS 1.15:4598 , AGARD Flight Mechanics Panel Symposium; May 09, 1994 - May 12, 1994; Turin; Italy

Format: application/pdf

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7

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In-flight flow visualization results from the X-29A aircraft at high angles of attack (1992)

Delfrate, John H. ; Saltzman, John A.

In: CASI

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Publication Date: 2019-07-13

Description: Flow visualization techniques were used on the X-29A aircraft at high angles of attack to study the vortical flow off the forebody and the surface flow on the wing and tail. The forebody vortex system was studied because asymmetries in the vortex system were suspected of inducing uncommanded yawing moments at zero sideslip. Smoke enabled visualization of the vortex system and correlation of its orientation with flight yawing moment data. Good agreement was found between vortex system asymmetries and the occurrence of yawing moments. Surface flow on the forward-swept wing of the X-29A was studied using tufts and flow cones. As angle of attack increased, separated flow initiated at the root and spread outboard encompassing the full wing by 30 deg angle of attack. In general, the progression of the separated flow correlated well with subscale model lift data. Surface flow on the vertical tail was also studied using tufts and flow cones. As angle of attack increased, separated flow initiated at the root and spread upward. The area of separated flow on the vertical tail at angles of attack greater than 20 deg correlated well with the marked decrease in aircraft directional stability.

Keywords: AERODYNAMICS

Type: NASA-TM-4430 , H-1825 , NAS 1.15:4430 , AIAA PAPER 92-4102 , Biennial Flight Test Conference; Aug 24, 1992 - Aug 26, 1992; Hilton Head, SC; United States

Format: application/pdf

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8

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Spatial and temporal adaptive procedures for the unsteady aerodynamic analysis of airfoils using unstructured meshes (1992)

Williams, Marc H. ; Hooker, John R. ; Batina, John T.

In: Other Sources

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Publication Date: 2019-07-13

Description: An algorithm which combines spatial and temporal adaption for the time integration of the two-dimensional Euler equations on unstructured meshes of triangles is presented. Spatial adaption involves mesh enrichment to add elements in high gradient regions of the flow and mesh coarsening to remove elements where they are no longer needed. Temporal adaption is a time accurate, local time stepping procedure which integrates the flow equations in each cell according to the local numerical stability constraint. The flow solver utilizes a four-stage Runge-Kutta time integration scheme with an upwind flux-split spatial discretization. Results obtained using spatial and temporal adaption indicate that highly accurate solutions can be obtained with a significant savings of computing time over global time stepping.

Keywords: AERODYNAMICS

Type: AIAA PAPER 92-2694 , AIAA Applied Aerodynamics Conference; Jun 22, 1992 - Jun 24, 1992; Palo Alto, CA; United States

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9

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Current status of computational methods for transonic unsteady aerodynamics and aeroelastic applications (1992)

Malone, John B. ; Edwards, John W.

In: CASI

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Publication Date: 2019-07-13

Description: The current status of computational methods for unsteady aerodynamics and aeroelasticity is reviewed. The key features of challenging aeroelastic applications are discussed in terms of the flowfield state: low-angle high speed flows and high-angle vortex-dominated flows. The critical role played by viscous effects in determining aeroelastic stability for conditions of incipient flow separation is stressed. The need for a variety of flow modeling tools, from linear formulations to implementations of the Navier-Stokes equations, is emphasized. Estimates of computer run times for flutter calculations using several computational methods are given. Applications of these methods for unsteady aerodynamic and transonic flutter calculations for airfoils, wings, and configurations are summarized. Finally, recommendations are made concerning future research directions.

Keywords: AERODYNAMICS

Type: NASA-TM-104191 , NAS 1.15:104191 , AGARD-PAPER-1 , AGARD Structures and Materials Panel Specialist''s Meeting on Transonic Unsteady Aerodynamics and Aeroelasticity; Oct 09, 1991 - Oct 11, 1991; San Diego, CA; United States

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10

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Spatial and temporal adaptive procedures for the unsteady aerodynamic analysis of airfoils using unstructured meshes (1992)

Hooker, John R. ; Batina, John T. ; Williams, Marc H.

In: CASI

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Publication Date: 2019-07-13

Description: An algorithm which combines spatial and temporal adaption for the time integration of the two dimensional Euler equations on unstructured meshes of triangles is presented. Spatial adaption involves mesh enrichment to add elements in high gradient regions of the flow and mesh coarsening to remove elements where they are no longer needed. Temporal adaption is a time accurate, local time stepping procedure which integrates the flow equations in each cell according to the local numerical stability constraint. The flow solver utilizes a four stage Runge-Kutta time integration scheme with an upwind flux-split spatial discretization. Results obtained using spatial and temporal adaption indicate that highly accurate solutions can be obtained with a significant savings of computing time over global time stepping.

Keywords: AERODYNAMICS

Type: NASA-TM-107635 , NAS 1.15:107635 , AIAA 10th Applied Aerodynamics Conference; Jun 22, 1992 - Jun 24, 1992; Palo Alto, CA; United States

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