Aeromechanical Response of a Distortion-Tolerant Boundary Layer Ingesting Fan

Provenza, Andrew J.; Duffy, Kirsten P.; Bakhle, Milind A.

doi:10.1115/1.4040739

Cited by 24 publications

(21 citation statements)

References 11 publications

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“…Further work is required to understand how flutter computations can be performed near the operating conditions where flutter occurred during the test. In addition, the observed structural mode 21,22 during flutter was mode 1 and a 2 ND pattern was identified through post-test data analysis. In contrast, the TURBO computations showed the lowest levels of aerodynamic damping for mode 2 and a 1 ND pattern.…”

Section: B Distorted Inflowmentioning

confidence: 99%

“…The fan blade forced response near a resonance is dominated by a single mode unless the modes are closely spaced. Since the lower modes of the DTF fan blade are well separated from each other [20][21][22] , it is not necessary to include other modes in the resonant response analysis. Further, the BLI distortion produces aerodynamic excitations that act as (backward) traveling waves on the fan blades and excite only specific blade modes with particular nodal diameter patterns when the dynamics of blade to blade differences in structural characteristics (mistuning) is not included in the formulation.…”

Section: Fan Blade Resonant Responsementioning

confidence: 99%

“…During the wind tunnel test, data was acquired [21][22] at this resonant crossing for aeromechanics code validation by increasing the fan rotational speed at a constant rate through this crossing. Analysis of the data provides the following information at resonance for each of 18 blades as measured by each of 7 probes: rotational speed, vibration frequency, response amplitude, and damping.…”

Section: Fan Blade Resonant Responsementioning

confidence: 99%

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Aeromechanics Analysis of a Distortion-Tolerant Fan with Boundary Layer Ingestion

Bakhle

Reddy

Coroneos

et al. 2018

2018 AIAA Aerospace Sciences Meeting

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A propulsion system with Boundary Layer Ingestion (BLI) has the potential to significantly reduce aircraft engine fuel burn. But a critical challenge is to design a fan that can operate continuously with a persistent BLI distortion without aeromechanical failure -flutter or high cycle fatigue due to forced response. High-fidelity computational aeromechanics analysis can be very valuable to support the design of a fan that has satisfactory aeromechanic characteristics and good aerodynamic performance and operability. Detailed aeromechanics analyses together with careful monitoring of the test article is necessary to avoid unexpected problems or failures during testing. In the present work, an aeromechanics analysis based on a three-dimensional, time-accurate, Reynolds-averaged Navier Stokes computational fluid dynamics code is used to study the performance and aeromechanical characteristics of the fan in both circumferentially-uniform and circumferentially-varying distorted flows. Pre-test aeromechanics analyses are used to prepare for the wind tunnel test and comparisons are made with measured blade vibration data after the test. The analysis shows that the fan has low levels of aerodynamic damping at various operating conditions examined. In the test, the fan remained free of flutter except at one near-stall operating condition. Analysis could not be performed at this low mass flow rate operating condition since it fell beyond the limit of numerical stability of the analysis code. The measured resonant forced response at a specific low-response crossing indicated that the analysis under-predicted this response and work is in progress to understand possible sources of differences and to analyze other larger resonant responses. Follow-on work is also planned with a coupled inlet-fan aeromechanics analysis that will more accurately represent the interactions between the fan and BLI distortion.

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Section: B Distorted Inflowmentioning

confidence: 99%

Section: Fan Blade Resonant Responsementioning

confidence: 99%

Section: Fan Blade Resonant Responsementioning

confidence: 99%

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Aeromechanics Analysis of a Distortion-Tolerant Fan with Boundary Layer Ingestion

Bakhle

Reddy

Coroneos

et al. 2018

2018 AIAA Aerospace Sciences Meeting

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“…7) may occur close to idle speed, and could be excited during descent. The 2EO/M1 crossing had significantly higher response than any other mode crossing, although it remained below the modified Goodman stress limit [6]. However, the high response prompted the development of a fan/tunnel startup/shutdown procedure to limit the duration and magnitude of the resonant response.…”

Section: Fan Blade Vibration Modesmentioning

confidence: 99%

“…The blades were designed such that the predicted worst case stress level at the Aerodynamic Design Point (ADP) at 100% speed was less than the modified Goodman limit; however, with the distorted flow it was critical to measure blade vibrations at all rotor speeds and aerodynamic conditions throughout the test. Strain gages were placed in several locations on a few of the blades, and those test results are presented in detail by Provenza [6]. Additionally, a Non-contacting Stress Measurement System (NSMS) consisting of laser probes was used to measure the blade tip circumferential displacement during the test.…”

Section: Introductionmentioning

confidence: 99%

Laser Displacement Measurements of Fan Blades in Resonance and Flutter During the Boundary Layer Ingesting Inlet and Distortion-Tolerant Fan Test

Duffy

Provenza

Bakhle

et al. 2018

2018 AIAA Aerospace Sciences Meeting

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NASA's Advanced Air Transport Technology Project is investigating boundary layer ingesting propulsors for future subsonic commercial aircraft to improve aircraft efficiency, thereby reducing fuel burn. To that end, a boundary layer ingesting inlet and distortiontolerant fan stage were designed, fabricated, and tested within the 8'x6' Supersonic Wind Tunnel at NASA Glenn Research Center. Because of the distortion in the air flow ingested by the fan, the blades were designed to withstand a much higher aerodynamic forcing than for a typical clean flow. The blade response for several resonance modes was measured during start-up and shutdown, as well as at near 85% design speed. Flutter in the first bending mode was also observed in the fan at the design speed, at an off-design condition, although instabilities were difficult to instigate with this fan in general. Blade vibrations were monitored through twelve laser displacement probes that were placed around the inner circumference of the casing, at the blade leading and trailing edges. These probes captured the movement of all the blades during the entire test. In addition to blade vibration results, benefits and disadvantages of laser displacement probe measurements versus strain gage measurements are discussed.

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