On binary scaling and ground-to-flight extrapolation in high-enthalpy facilities

Looringhe, de Crombrugghe de; Arwid, Guerric

doi:10.14264/uql.2017.456

Cited by 8 publications

(2 citation statements)

References 112 publications

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“…Earth [54], Mars [33], Venus [55], Titan [56] and gas giant atmospheres [38] in expansion tube mode or non-reflected shock tube mode (straight acceleration tube into test section, no nozzle, no model) [57] as well as high-pressure scramjet conditions (straight acceleration tube into test section, no nozzle) [6] [58].…”

Section: Experiments In the X2 Free-piston Driven Expansion Tube 22mentioning

confidence: 99%

Superorbital re-entry shock layers: flight and laboratory comparisons

Fahy¹

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Hypervelocity re-entry through the Earth's atmosphere surrounds an aeroshell with a radiating shock layer, which has complex and potentially critical interactions with the thermal protection system, the key component to the vehicle's survival. Aerothermodynamic re-entry flight data is rare, but the available radiation data has potential for replication in ground-based experimental and numerical testing, where flight equivalent conditions can be achieved. A greater understanding and ability to demonstrate the behaviour of re-entry vehicles will allow increased confidence in pre-flight laboratory predictions, design iterations based on testing and simulation, and an overall reduction in the thermal protection system (TPS) mass, therefore increasing the mass available for scientific payload. This thesis aims to replicate flight data from the unmanned Hayabusa and Stardust aeroshell re-entries in expansion tube experiments and numerical simulations, and assess the similarities and differences in the results. The flight data is in the form of infrared (IR) and ultraviolet (UV) spectra emanating from the bow shock, as captured by air-and ground-based observation missions.The experiments were performed in the X2 expansion tube, a hypervelocity impulse facility capable of producing flight equivalent conditions over a scaled aeroshell model for a brief test time. Prior to optical imaging tests, the conditions were designed through an iterative combination of analytical, experimental and numerical methods, based on binary scaling and enthalpy matching. Emissions from the radiating shock layers were captured by IR and UV spectroscopy, as well as two-dimensional intensity mapping through a narrow wavelength band filter, but the measurements were oriented differently to flight. The axisymmetry of certain imaging planes enabled the transformation of line of sight integrated intensities into radial quantities, which could describe the forebody shock layer and result in an integrated intensity comparable with integrated flight spectra.Numerical simulations must first model the flowfield before radiation modelling is possible. Compressible flow computational fluid dynamics (CFD) simulations were performed for the Hayabusa and Stardust flight vehicles at the selected trajectory points, and scaled models at idealised and simulated inflow conditions. Radiation spectra calculations were performed along the same lines of sight as imaged in experimental spectra, and over the entire flowfield to be comparable to flight data and experimental 2D imaging.iii The flight, experimental and numerical data combined for a series of comparisons to test the hypotheses that under binary scaling, spectral radiance along a line of sight is invariant, and radiative intensity scales with the square of the length scale. Spectra comparisons between experiment and CFD, and CFD and flight, tested the first hypothesis, and integrated intensity comparisons between experiment and CFD, and experiment and flight, tested the second hypothesis. Favourabl...

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Section: Experiments In the X2 Free-piston Driven Expansion Tube 22mentioning

confidence: 99%

Superorbital re-entry shock layers: flight and laboratory comparisons

Fahy¹

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“…These additional parameters make it necessary to build a scale model. Binary scaling is usually used as it conserves the Reynolds number and binary reaction rates present in the non-equilibrium layer [22]. This approach is appropriate for chemical kinetics and conductive transfer but not always for radiative transfer [7].…”

Section: Binary Scalingmentioning

confidence: 99%

Simulation of CubeSat re-entry trajectory

Apirana¹

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Von Karman Institute in partnership with Ecole Centrale Paris are launching the QB50 program, comprising 50 CubeSats capable of performing scientific experiments in the thermosphere. One of these Cubesats, QARMAN, is designed to make measurements of ablation to inform the design of thermal protection systems for re-entry vehicles.QARMAN will deploy a passive braking system upon re-entry to the atmosphere and peak-heating is expected to occur at an altitude of 50km. This was the design point for trajectory modelling. The re-entry velocity was determined to be in the range of 7.5 -7.57km/s. The resulting velocity at peak-heating was found to be 6.35km/s using the lower bound of the entry velocity range.A computational model was built to simulate the flow conditions over QARMAN during peak heating. The compressible flow code, eilmer3, was used and a 2D model was built subject to simplifying assumptions of the geometry of QARMAN. Bow-shock, boundary layer, and oblique-shock interactions were observed, and the boundary layer displacement thickness was measured to be 6.89mm at a distance 340mm downstream of the nose. A shock stand-off distance, influenced by boundary layer propagation, was observed, and measured to be 52.8mm upstream of the interface of fore-body and wedge-tip. This represents a stand-off distance that is 7.66 times the displacement thickness which is significantly larger than the commonly used 4x multiplier.A 3:10 scaled-model of QARMAN was designed and built. A recess within the model allows for gauges to measure heat data, and the location of 8 holes to house thin-film gauges has been outlines. Two additional mounting pieces were designed and built to hold the model in the test section and these can be used for mounting other models.An experiment has been designed for The University of Queensland's X2 expansion tube.The post-shock density was found and binary scaling was used to determine an appropriate driver gas configuration. Analytical calculation of the boundary layer thickness was compared with the CFD output and a difference between their predicted shock stand-off distances was found. The positioning of sensors was designed to capture this region of interest and comparison between experiments, CFD, and analytical predictions is recommended.

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