Characterization of Complex Porous Structures for Reusable Thermal Protection Systems: Effective-Permeability Measurements

Gulli, Stefano; Maddalena, Luca

doi:10.2514/1.a32980

Cited by 16 publications

(11 citation statements)

References 28 publications

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“…The correct probing distance is fundamental to obtain meaningful velocity measurements in terms of minimum fluctuations with respect to the mean velocity field ( Fig. 11 in [6]). In fact, in the near-wall region, single jets are discernable with a pattern that mimics the perforated arrangement of the porous surface, whereas, at the merging distance (L m ), the jets coalesce together [7].…”

Section: Measurements Methodology and Data Analysismentioning

confidence: 99%

“…The influence of the probe distance from the wall has been analyzed by applying the theory of fluid flow through perforated plates/screens that allowed identifying the range of optimal distances for the mass flux measurements [6][7][8]. The correct probing distance is fundamental to obtain meaningful velocity measurements in terms of minimum fluctuations with respect to the mean velocity field ( Fig.…”

Section: Measurements Methodology and Data Analysismentioning

confidence: 99%

“…The 2-D segmentation of several planes, longitudinal and perpendicular to the centerline of the sample (Figs. 2 and 3, respectively), has been used for defining two fundamental parameters needed to correctly perform the permeability tests by hot-film anemometry [6].…”

Section: Measurements Methodology and Data Analysismentioning

confidence: 99%

“…10 is referred (CS9), corresponds to the region above the internal plenum that has variable thickness (Figs. 2a and 8b in [6]). …”

Section: B Dimensions Of the Probed Areamentioning

confidence: 95%

“…The output data from the CT scan allows defining the most important guidelines needed to correctly perform the local effectivepermeability measurements [6]. In particular, the two-dimensional (2-D) sectioning and the three-dimensional (3-D) digital reconstruction of the specimen have been used to calculate, first, the internal porosity of the prototype specimen and, then, to define the minimum dimension of the characteristic area, or control surface (CS), to be probed for the mass flux measurement (Sec.…”

mentioning

confidence: 99%

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Characterization of Complex Porous Structures for Reusable Thermal Protection Systems: Porosity Measurements

Gulli

Maddalena²,

McKelvey

et al. 2015

Journal of Spacecraft and Rockets

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This work is focused on the nonintrusive characterization of the local and average porosity of a prototype carboncarbon nose, representative of a reusable thermal protection system based on transpiration cooling. A study based on the x-ray computed tomography scan of the specimen has been carried out with the purpose of defining the most important guidelines for the permeability tests, which are the minimum area to be probed with a hot-film anemometer and the correct distance of the mass flux sensor from the wall. The former has been calculated from the average porosity calculation, whereas the latter has been retrieved from the statistical analysis of the dimensions, and the distribution of the void structures inside the porous network coupled to the theory of fluid flow through perforated plates. Several longitudinal and transversal sectioning planes with respect to the symmetry axis of the carbon mask have been analyzed to calculate the internal porosity from the two-dimensional images, whereas the threedimensional reconstruction of the sample has been used to retrieve the average volumetric porosity. Both the nominal values of the two-dimensional porosity and volumetric porosity have provided the same dimension of the characteristic area to be probed with a hot-film sensor for the permeability measurements. Preliminary permeability tests, performed within the predicted dimension of the control surface, have confirmed the uniformity of the mean velocity field and allowed verifying the range of variation of the correct distance of a hot-film sensor from the wall obtained from the statistical analysis of the computed tomography images. Nomenclature D ch = channel diameter, μm D CS = diameter of control points, in. d w = transversal distance from wall, in. H = local specimen thickness, in. l = length, μm L m = merging or coalescence distance, in. M = network-mesh size, in. _ m = measured flow rate, SLPM Re ch = Reynolds number based on channel diameter, -R 2 = coefficient of determination, -u = seepage or interstitial velocity, m∕s ε sup = superficial porosity, -ε 2-D = porosity calculated from 2-D CT images, -ε 3-D = volumetric porosity, -τ = tortuosity, -Subscripts ch = channels eff = effective N 2 = nitrogen REV = reference elementary volume RES = reference elementary surface st = straight channel t = tortuous channel

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Section: Measurements Methodology and Data Analysismentioning

confidence: 99%

Section: Measurements Methodology and Data Analysismentioning

confidence: 99%

Section: Measurements Methodology and Data Analysismentioning

confidence: 99%

“…10 is referred (CS9), corresponds to the region above the internal plenum that has variable thickness (Figs. 2a and 8b in [6]). …”

Section: B Dimensions Of the Probed Areamentioning

confidence: 95%

mentioning

confidence: 99%