In-Flight Aeroelastic Stability of the Thermal Protection System on the NASA HIAD, Part I: Linear Theory

Goldman, Benjamin D.; Dowell, Earl H.; Scott, Robert C.

doi:10.2514/6.2014-1520

Cited by 2 publications

(5 citation statements)

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“…To verify that the time-integration scheme has been implemented correctly, various comparisons were made with the linear theory used in Part I. 1 Note that this linear analysis was found to be consistent with previously published results on the free vibrations and flutter of conical shells. First, a buckling analysis was computed in the time domain, using the critical circumferential buckling mode (n crit = 43) found in the eigenanalysis (for the 6-meter configuration), and neglecting all nonlinear terms.…”

Section: Iva Verification Convergence Studies and Linear/nonlinear Model Comparisonsupporting

confidence: 59%

“…The first set of results are from validation studies, ensuring that the nonlinear buckling and aeroelastic simulations are consistent with the linear theory in Part I. 1 Next, deflection shapes and strains for a static load simulation are presented, corresponding to experimental tests performed on a 6-meter HIAD article. Aeroelastic limit cycle oscillations are then calculated for various cases, and the effects of axially-applied tension are examined for the 3-meter geometry.…”

Section: Resultsmentioning

confidence: 99%

“…Details on the thermal protection system modeling can be found in reference [1]. A brief summary of the structural models and TPS will be provided here, since the current analysis is based on the previous work.…”

Section: Background and Previous Workmentioning

confidence: 99%

“…Nonlinear aeroelastic solutions are calculated by first performing the linear analysis described in Part I. 1 Linear theory predicts a single critical circumferential mode as well as coalescence of two axial modes at the flutter dynamic pressure. A nonlinear time integration simulation is then performed with initial conditions (displacements) in the coordinates for these critical modes only.…”

Section: Iiia Nonlinear Aeroelastic Equations Of Motionmentioning

confidence: 99%

“…The purpose of this report series, consisting of the current work and reference [1], is to characterize the in-flight aeroelastic behavior of a proposed thermal protection system 2 for the NASA Hypersonic Inflatable Aerodynamic Decelerator (HIAD). 3 The HIAD is an inflatable aeroshell with a diameter significantly larger than that of current rigid aeroshells.…”

Section: Introductionmentioning

confidence: 99%

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In-Flight Aeroelastic Stability of the Thermal Protection System on the NASA HIAD, Part II: Nonlinear Theory and Extended Aerodynamics

Goldman

Dowell

Scott

2015

56th AIAA/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference

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Conical shell theory and a supersonic potential flow aerodynamic theory are used to study the nonlinear pressure buckling and aeroelastic limit cycle behavior of the thermal protection system for NASA's Hypersonic Inflatable Aerodynamic Decelerator. The structural model of the thermal protection system consists of an orthotropic conical shell of the Donnell type, resting on several circumferential elastic supports. Classical Piston Theory is used initially for the aerodynamic pressure, but was found to be insufficient at low supersonic Mach numbers. Transform methods are applied to the convected wave equation for potential flow, and a time-dependent aerodynamic pressure correction factor is obtained. The Lagrangian of the shell system is formulated in terms of the generalized coordinates for all displacements and the Rayleigh-Ritz method is used to derive the governing differential-algebraic equations of motion. Aeroelastic limit cycle oscillations and buckling deformations are calculated in the time domain using a Runge-Kutta method in MATLAB.Three conical shell geometries were considered in the present analysis: a 3-meter diameter 70 • cone, a 3.7-meter 70 • cone, and a 6-meter diameter 70 • cone. The 6-meter configuration was loaded statically and the results were compared with an experimental load test of a 6-meter HIAD. Though agreement between theoretical and experimental strains was poor, the circumferential wrinkling phenomena observed during the experiments was captured by the theory and axial deformations were qualitatively similar in shape. With Piston Theory aerodynamics, the nonlinear flutter dynamic pressures of the 3meter configuration were in agreement with the values calculated using linear theory, and the limit cycle amplitudes were generally on the order of the shell thickness. The effect of axial tension was studied for this configuration, and increasing tension was found to decrease the limit cycle amplitudes when the circumferential elastic supports were neglected, but resulted in more complex behavior when the supports were included. The nominal flutter dynamic pressure of the 3.7-meter configuration was significantly lower than that of the 3-meter, and it was found that two sets of natural modes coalesce to flutter modes near the same dynamic pressure. This resulted in a significant drop in the limit cycle frequencies at higher dynamic pressures, where the flutter mode with the lower frequency becomes more critical. Pre-buckling pressure loads and the aerodynamic pressure correction factor were studied for all geometries, and these effects resulted in significantly lower flutter boundaries compared with Piston Theory alone. The maximum dynamic pressure predicted by aerodynamic simulations of a proposed 3.7-meter HIAD vehicle was still lower than any of the calculated flutter dynamic pressures, suggesting that aeroelastic effects for this vehicle are of little concern.

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Section: Iva Verification Convergence Studies and Linear/nonlinear Model Comparisonsupporting

confidence: 59%

Section: Resultsmentioning

confidence: 99%

Section: Background and Previous Workmentioning

confidence: 99%

Section: Iiia Nonlinear Aeroelastic Equations Of Motionmentioning

confidence: 99%