An Experimental Investigation of the 30P30N Multi-Element High-Lift Airfoil

Pascioni, Kyle A.; Cattafesta, Louis N.; Choudhari, Meelan M.

doi:10.2514/6.2014-3062

Cited by 51 publications

(29 citation statements)

References 13 publications

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“…Figures 7 and 10, show noise spectra for such lower angles of attack are broadband-like and their noise intensity levels are closer to those of the wind-tunnel. The slat noise components of multiple tonal peaks of low-frequency and high-frequency broad tone,, 17,10,38,10,18,39,23,13,40,5,6,41,42,9,8,19 emerges after an increase in the angle of attack, i. e., after −2 • . For higher angles of attack, i. e., above 10 • , the multiple tonal peaks component is suppressed and the broadband component emerges, but in a lower intensity than that of lower angles of attack employed.…”

Section: Acoustic Database Resultsmentioning

confidence: 99%

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Experiments on Slat Noise from -6° to 18° Angles of Attack

Amaral

Pagani

Himeno

et al. 2016

46th AIAA Fluid Dynamics Conference

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This study focuses on investigating the slat noise of a two-dimensional scaled, unswept and untapered, MD30P30N high-lift model. The database refers aeroacoustic and aerodynamic measurements in a closed-section wind tunnel for a wide range of angles of attack, namely from −6 • and 18 • , and Mach number ranging from 0.07 to 0.1. Aeroacoustic measurements were carried using a wall-mounted microphone array. The signal processing applied to the acoustic data involved conventional beamforming enhanced by two deconvolution algorithms, DAMAS and CLEAN-SC. Suction-based wall boundary-layer control was applied to provide a more two dimensional flow over the model span. Chord-wise and span-wise static pressure measurements were performed. Slat noise spectra revel low-frequency tones, broadband noise and a single broad tone in the higher frequency range. The results show all slat noise components are strongly affected by wing angle of attack. The low-frequency tones vanish at lower negative wing angles of attack but reach their higher level at lower positive angles of attack. The tones level variation within a narrow range of angles of attack may be over 10 dB/Hz. Overall, the dominant part in the slat noise spectra reduces as the wing angle of attack increases, rendering higher frequency noise components potential contributors to the overall noise.

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Section: Acoustic Database Resultsmentioning

confidence: 99%

“…Slat noise has been studied from wind tunnel measurements 5,6,7,8,9 , numerical simulations 10,11,12,13,14,15 , and flyover tests 16 . Wind tunnel experiments using scaled high-lift models have revealed a slat noise signature featuring from broadband to tonal noise components.…”

Section: Introductionmentioning

confidence: 99%

Experiments on Slat Noise from -6° to 18° Angles of Attack

Amaral

Pagani

Himeno

et al. 2016

46th AIAA Fluid Dynamics Conference

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“…The 2-D geometry of the 30P30N configuration is simple enough to allow a broad set of flow solvers to be applied, which is confirmed by the previous observation that this configuration has been embraced in a variety of workshops with rather different objectives. 18,26,37 The low Reynolds number in Category 7 of the BANC-III workshop also implies that boundary layer transition over the slat should not be a major influence on the overall computation because the flow over the majority of the slat is laminar at this Re. Separation points on the slat are fixed by the model geometry; however, the reattachment location is jointly determined by the overall surface pressure distribution and the accuracy in predicting the evolution of unsteady flow structures along the shear layer that bounds the separated flow region within the slat cove.…”

Section: Simplifications and Challengesmentioning

confidence: 97%

“…17 Category 7 of the BANC series of workshops targets the slat cove noise associated with the generic, zero sweep, 30P30N high-lift configuration. 18 For the BANC-III Workshop, a total of twelve teams performed computational predictions of various aerodynamic and aeroacoustic metrics ranging from mean and unsteady force coefficients, surface pressure distributions including power spectral density (PSD) and spanwise coherence, off-body velocity field in regions of attached and separated flow, and acoustic spectra representative of flyover measurements. Three other teams contributed complementary information derived from previously conducted simulations for the same geometry and either the same or related flow conditions.…”

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confidence: 99%

Assessment of Slat Noise Predictions for 30P30N High-Lift Configuration from BANC-III Workshop

Choudhari

Lockard

2015

21st AIAA/CEAS Aeroacoustics Conference

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This paper presents a summary of the computational predictions and measurement data contributed to Category 7 of the 3 rd AIAA Workshop on Benchmark Problems for Airframe Noise Computations (BANC-III), which was held in Atlanta, GA, on June 14-15, 2014. Category 7 represents the first slat-noise configuration to be investigated under the BANC series of workshops, namely, the 30P30N two-dimensional high-lift model (with a slat contour that was slightly modified to enable unsteady pressure measurements) at an angle of attack that is relevant to approach conditions. Originally developed for a CFD challenge workshop to assess computational fluid dynamics techniques for steady high-lift predictions, the 30P30N configurations has provided a valuable opportunity for the airframe noise community to collectively assess and advance the computational and experimental techniques for slat noise. The contributed solutions are compared with each other as well as with the initial measurements that became available just prior to the BANC-III Workshop. Specific features of a number of computational solutions on the finer grids compare reasonably well with the initial measurements from FSU and JAXA facilities and/or with each other. However, no single solution (or a subset of solutions) could be identified as clearly superior to the remaining solutions. Grid sensitivity studies presented by multiple BANC-III participants demonstrated a relatively consistent trend of reduced surface pressure fluctuations, higher levels of turbulent kinetic energy in the flow, and lower levels of both narrow band peaks and the broadband component of unsteady pressure spectra in the nearfield and farfield. The lessons learned from the BANC-III contributions have been used to identify improvements to the problem statement for future Category-7 investigations. Nomenclature a = speed of sound b sim = spanwise extent of simulation domain b = model span c = chord length of stowed configuration = 0.4572 m (18 inches) c s = slat chord C d = computed overall drag coefficient (scaled by planform area c⋅b sim ) C L = computed overall lift coefficient (scaled by planform area c⋅b sim ) C L, RMS= computed RMS lift coefficient (scaled by planform area c⋅b sim ) C L,s = contribution to overall lift coefficient (scaled by planform area c⋅b sim ) from slat C L,m = contribution to overall lift coefficient (scaled by planform area c⋅b sim ) from main wing C L,f = contribution to overall lift coefficient (scaled by planform area c⋅b sim ) from flap 1 Aerospace Technologist, Computational AeroSciences Branch, M.S. 128. Associate Fellow, AIAA. 2 Aerospace Technologist, Computational AeroSciences Branch, M.S. 128. Senior Member, AIAA. 3 Team members are listed in Table 1. Downloaded by PURDUE UNIVERSITY on July 26, 2015 | http://arc.aiaa.org | 2 Cp = surface pressure coefficient = (p-p ∞ )/(ρ ∞ U ∞ 2)/2 d impingement = distance between shear layer impingement location and slat trailing edge, normalized by c K = coverage factor for confidence interval L xy = minimum distanc...

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“…The typical geometry of a high-lift airfoil from leading edge to trailing edge consists of three parts: slat, main and flap. As shown in The 30P30N is a well-studied high-lift airfoil; geometric settings such as the gap and overhang of the slat and the flap are summarized in Table 2.1 [8].…”

Section: Geometrymentioning

confidence: 99%

Numerical Determination of Critical Mach Number of a Three -Element Airfoil in Unbounded Flow and in Ground Effect

2018

2018 Applied Aerodynamics Conference

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An Experimental Investigation of the 30P30N Multi-Element High-Lift Airfoil

Cited by 51 publications

References 13 publications

Experiments on Slat Noise from -6° to 18° Angles of Attack

Experiments on Slat Noise from -6° to 18° Angles of Attack

Assessment of Slat Noise Predictions for 30P30N High-Lift Configuration from BANC-III Workshop

Numerical Determination of Critical Mach Number of a Three -Element Airfoil in Unbounded Flow and in Ground Effect

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