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Investigations of High Pressure Acoustic Waves in Resonators with Seal-Like Features (2004)

Steinetz, Bruce M. ; Li, Xiao-Fan ; Finkbeiner, Joshua R. ; [et al.]

In: CASI

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Publication Date: 2018-06-06

Description: 1) Standing waves with maximum pressures of 188 kPa have been produced in resonators containing ambient pressure air; 2) Addition of structures inside the resonator shifts the fundamental frequency and decreases the amplitude of the generated pressure waves; 3) Addition of holes to the resonator does reduce the magnitude of the acoustic waves produced, but their addition does not prohibit the generation of large magnitude non-linear standing waves; 4) The feasibility of reducing leakage using non-linear acoustics has been confirmed.

Keywords: Acoustics

Type: 2003 NASA Seal/Secondary Air System Workshop, Volume 1; 239-271; NASA/CP-2004-212963/VOL1

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2

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Effect of Forcing Function on Nonlinear Acoustic Standing Waves (2003)

Finkheiner, Joshua R. ; Raman, Ganesh ; Daniels, Chris ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: Nonlinear acoustic standing waves of high amplitude have been demonstrated by utilizing the effects of resonator shape to prevent the pressure waves from entering saturation. Experimentally, nonlinear acoustic standing waves have been generated by shaking an entire resonating cavity. While this promotes more efficient energy transfer than a piston-driven resonator, it also introduces complicated structural dynamics into the system. Experiments have shown that these dynamics result in resonator forcing functions comprised of a sum of several Fourier modes. However, previous numerical studies of the acoustics generated within the resonator assumed simple sinusoidal waves as the driving force. Using a previously developed numerical code, this paper demonstrates the effects of using a forcing function constructed with a series of harmonic sinusoidal waves on resonating cavities. From these results, a method will be demonstrated which allows the direct numerical analysis of experimentally generated nonlinear acoustic waves in resonators driven by harmonic forcing functions.

Keywords: Acoustics

Type: Paper 4aPAa2 , 145th Acoustic Society of America Conference; Apr 28, 2003 - May 02, 2003; Nashville, TN; United States

Format: text

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3

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Screech Tones of Supersonic Jets from Bevelled Rectangular Nozzles (1997)

Raman, Ganesh ; Tam, Christopher K. W. ; Shen, Hao

In: CASI

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Publication Date: 2019-07-13

Description: It is known experimentally that an imperfectly expanded rectangular jet from a thin-lip convergent nozzle emits only a single dominant screech tone. The frequency of the screech tone decreases continuously with increase in jet Mach number. However, for a supersonic jet issued from a bevelled nozzle or a convergent-divergent nozzle with straight side walls, the shock cell structure and the screech frequency pattern are fairly complicated and have not been predicted before. In this paper, it is shown that the shock cell structures of these jets can be decomposed into waveguide modes of the jet flow. The screech frequencies are related to the higher-order waveguide modes following the weakest-link screech tone theory. The measured screech frequencies are found to compare well with the predicted screech frequency curves.

Keywords: Acoustics

Type: NASA-CR-205131 , AIAA Paper 95-0143 , NAS 1.26:205131 , Aerospace Sciences Meeting &amp; Exhibit; Jan 06, 1997 - Jan 10, 1997; Reno, NV; United States

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4

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Modeling Nonlinear Acoustic Standing Waves in Resonators: Theory and Experiments (2004)

Li, Xiaofan ; Raman, Ganesh ; Finkbeiner, Joshua

In: CASI

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Publication Date: 2019-07-10

Description: The overall goal of the cooperative research with NASA Glenn is to fundamentally understand, computationally model, and experimentally validate non-linear acoustic waves in enclosures with the ultimate goal of developing a non-contact acoustic seal. The longer term goal is to transition the Glenn acoustic seal innovation to a prototype sealing device. Lucas and coworkers are credited with pioneering work in Resonant Macrosonic Synthesis (RMS). Several Patents and publications have successfully illustrated the concept of Resonant Macrosonic Synthesis. To utilize this concept in practical application one needs to have an understanding of the details of the phenomenon and a predictive tool that can examine the waveforms produced within resonators of complex shapes. With appropriately shaped resonators one can produce un-shocked waveforms of high amplitude that would result in very high pressures in certain regions. Our goal is to control the waveforms and exploit the high pressures to produce an acoustic seal. Note that shock formation critically limits peak-to-peak pressure amplitudes and also causes excessive energy dissipation. Proper shaping of the resonator is thus critical to the use of this innovation.

Keywords: Acoustics

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A Study of Standing Pressure Waves Within Open and Closed Acoustic Resonators (2002)

Steinetz, B. ; Li, X. ; Finkbeiner, J. ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: The first section of the results presented herein was conducted on an axisymmetric resonator configured with open ventilation ports on either end of the resonator, but otherwise closed and free from obstruction. The remaining section presents the results of a similar resonator shape that was closed, but contained an axisymmetric blockage centrally located through the axis of the resonator. Ambient air was used as the working fluid. In each of the studies, the resonator was oscillated at the resonant frequency of the fluid contained within the cavity while the dynamic pressure, static pressure, and temperature of the fluid were recorded at both ends of the resonator. The baseline results showed a marked reduction in the amplitude of the dynamic pressure waveforms over previous studies due to the use of air instead of refrigerant as the working fluid. A sharp reduction in the amplitude of the acoustic pressure waves was expected and recorded when the configuration of the resonators was modified from closed to open. A change in the resonant frequency was recorded when blockages of differing geometries were used in the closed resonator, while acoustic pressure amplitudes varied little from baseline measurements.

Keywords: Acoustics

Type: 145th Acoustic Society of America Conference; Dec 02, 2002 - Dec 06, 2002; Cancun; Mexico

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Nonlinear Resonant Oscillations of Gas in Optimized Acoustical Resonators and the Effect of Central Blockage (2003)

Daniels, Christopher ; Finkbeiner, Joshua ; Steinetz, Bruce M. ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: Optimizing resonator shapes for maximizing the ratio of maximum to minimum gas pressure at an end of the resonator is investigated numerically. It is well known that the resonant frequencies and the nonlinear standing waveform in an acoustical resonator strongly depend on the resonator geometry. A quasi-Newton type scheme was used to find optimized axisymmetric resonator shapes achieving the maximum pressure compression ratio with an acceleration of constant amplitude. The acoustical field was solved using a one-dimensional model, and the resonance frequency shift and hysteresis effects were obtained through an automation scheme based on continuation method. Results are presented for optimizing three types of geometry: a cone, a horn-cone and a half cosine-shape. For each type, different optimized shapes were found when starting with different initial guesses. Further, the one-dimensional model was modified to study the effect of an axisymmetric central blockage on the nonlinear standing wave.

Keywords: Acoustics

Type: NASA/TM-2003-212019 , NAS 1.15:212019 , E-13723 , AIAA Paper 2003-0368 , 41st Aerospace Science Meeting and Exhibit; Jan 06, 2003 - Jan 09, 2003; Reno, NV; United States

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7

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Nonlinear Oscillations and Flow of Gas Within Closed and Open Conical Resonators (2004)

Li, Xiaofan ; Daniels, Christopher ; Finkbeiner, Joshua ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: A dissonant acoustic resonator with a conical shaped cavity was tested in four configurations: (A) baseline resonator with closed ends and no blockage; (B) closed resonator with internal blockage; (C) ventilated resonator with no blockage; and (D) ventilated resonator with an applied pressure differential. These tests were conducted to investigate the effects of blockage and ventilation holes on dynamic pressurization. Additionally, the investigation was to determine the ability of acoustic pressurization to impede flow through the resonator. In each of the configurations studied, the entire resonator was oscillated at the gas resonant frequency while dynamic pressure, static pressure, and temperature of the fluid were measured. In the final configuration, flow through the resonator was recorded for three oscillation conditions. Ambient condition air was used as the working fluid. The baseline results showed a marked reduction in the amplitude of the dynamic pressure waveforms over previously published studies due to the use of air instead of refrigerant as the working fluid. A change in the resonant frequency was recorded when blockages of differing geometries were used in the closed resonator, while acoustic pressure amplitudes were reduced from baseline measurements. A sharp reduction in the amplitude of the acoustic pressure waves was expected and recorded when ventilation ports were added. With elevated pressure applied to one end of the resonator, flow was reduced by oscillating the cavity at the fluid fundamental resonant frequency compared to cases without oscillation and oscillation off-resonance.

Keywords: Acoustics

Type: NASA/TM-2004-212902 , AIAA Paper 2004-0677 , NAS 1.15:212902 , E-14325 , 42nd Aerospace Sciences Meeting and Exhibit; Jan 05, 2004 - Jan 08, 2004; Reno, NV; United States

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8

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Determination of Dimensionless Attenuation Coefficient in Shaped Resonators (2003)

Steinetz, B. ; Daniels, C. ; Finkbeiner, J. ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: The value of dimensionless attenuation coefficient is an important factor when numerically predicting high-amplitude acoustic waves in shaped resonators. Both the magnitude of the pressure waveform and the quality factor rely heavily on this dimensionless parameter. Previous authors have stated the values used, but have not completely explained their methods. This work fully describes the methodology used to determine this important parameter. Over a range of frequencies encompassing the fundamental resonance, the pressure waves were experimentally measured at each end of the shaped resonators. At the corresponding dimensionless acceleration, the numerical code modeled the acoustic waveforms generated in the resonator using various dimensionless attenuation coefficients. The dimensionless attenuation coefficient that most closely matched the pressure amplitudes and quality factors of the experimental and numerical results was determined to be the value to be used in subsequent studies.

Keywords: Acoustics

Type: Paper-4aPAa3 , 145th Acoustical Society of America Conference; Apr 28, 2003 - May 02, 2003; Nashville, TN; United States

Format: text

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9

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Mode Spectra of Natural Disturbances in a Circular Jet and the Effect of Acoustic Forcing (1994)

Raman, G. ; Rice, E. J. ; Reshotko, E.

In: Other Sources

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Publication Date: 2019-07-13

Description: A modal spectrum technique was used to study coherent instability modes triggered by naturally occurring disturbances in a circular jet. This technique was applied to a high Reynolds number jet for both untripped and tripped nozzle exit boundary layers, with both cases having a core turbulence level of 0.15 percent. The region up to the end of the potential core was dominated by the axisymmetric mode, with the azimuthal modes dominating further downstream. The growth of the azimuthal modes was observed closer to the nozzle exit for the jet with a transitional boundary layer. Whether for locally parallel flow or slowly diverging flow, even at low levels of acoustic forcing, the inviscid linear theory is seen to be inadequate for predicting the amplitude of the forced mode. In contrast, the energy integral approach reasonably predicts the evolution of the forced mode.

Keywords: Acoustics

Type: E-7882 , Experiments in Fluids (ISSN 0723-4864); 17; 6; 415-426

Format: text

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10

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Quantitative Interferometry in the Severe Acoustic Environment of Resonant Supersonic Jets (1998)

Raman, Ganesh ; Mercer, Carolyn R.

In: Other Sources

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Publication Date: 2019-07-13

Description: There is renewed interest in the study of supersonic jets due to advances in high speed jet propulsion, supersonic combustion, and jet noise suppression for the next generation supersonic commercial transport. Understanding fundamental fluid dynamic and acoustic processes for these applications requires quantitative velocity, density and temperature measurements. In this paper we present data demonstrating a new, robust interferometer that can provide accurate data even in the presence of intense acoustic fields. This novel interferometer, the Liquid Crystal Point Diffraction Interferometer (LCPDI), was developed earlier for space flight experiments and is applied here to the case of a supersonic shock-containing jet. The LCPDI is briefly described, then integrated line-of-sight density data from the LCPDI for two underexpanded free jets are presented. The experimental shock spacings agree well with theory.

Keywords: Acoustics

Type: High Speed Jet Flows; Jun 21, 1998 - Jun 25, 1998; Washington, DC; United States

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