'Product Improvement Test of UH-1 Main Rotor Blades with Erosion-Resistant Leading-Edge Coating'

Successful icing/de-icing simulations for rotorcraft require a good prediction of the convective heat transfer on the blade’s surface. Rotorcraft icing is an unwanted phenomenon that is known to cause flight cancelations, loss of rotor performance and severe vibrations that may have disastrous and deadly consequences. Following a series of experiments carried out at the Anti-icing Materials International Laboratory (AMIL), this paper provides heat transfer measurements on heated rotor blades, under both the anti-icing and de-icing modes in terms of the Nusselt Number (Nu). The objective is to develop correlations for the Nu in the presence of (1) an ice layer on the blades (NuIce) and (2) liquid water content (LWC) in the freestream with no ice (NuWet). For the sake of comparison, the NuWet and the NuIce are compared to heat transfer values in dry runs (NuDry). Measurements are reported on the nose of the blade-leading edge, for three rotor speeds (Ω) = 500, 900 and 1000 RPM; a pitch angle (θ) = 6°; and three different radial positions (r/R), r/R = 0.6, 0.75 and 0.95. The de-icing tests are performed twice, once for a glaze ice accretion and another time for rime ice. Results indicate that the NuDry and the NuWet directly increased with V∝, r/R or Ω, mainly due to an increase in the Reynolds number (Re). Measurements indicate that the NuWet to NuDry ratio was always larger than 1 as a direct result of the water spray addition. NuIce behavior was different and was largely affected by the ice thickness (tice) on the blade. However, the ice acted as insulation on the blade surface and the NuIce to NuDry ratio was always less than 1, thus minimizing the effect of convection. Four correlations are then proposed for the NuDry, the NuWet and the NuIce, with an average error between 3.61% and 12.41%. The NuDry correlation satisfies what is expected from heat transfer near the leading edge of an airfoil, where the NuDry correlates well with Re0.52.

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Influence of Leading Edge Fillet and Nonaxisymmetric Contoured Endwall on Turbine NGV Exit Flow Structure and Interactions With the Rim Seal Flow

Volume 6A: Turbomachinery ◽

10.1115/gt2013-95843 ◽

2013 ◽

Cited By ~ 5

Author(s):

Özhan H. Turgut ◽

Cengiz Camcı

Keyword(s):

Flow Structure ◽

Total Pressure ◽

Guide Vane ◽

Axial Flow ◽

Leading Edge ◽

Turbine Rotor ◽

Rotor Blades ◽

Constant Thickness ◽

Computational Evaluation ◽

Nozzle Guide

Three different ways are employed in the present paper to reduce the secondary flow related total pressure loss. These are nonaxisymmetric endwall contouring, leading edge (LE) fillet, and the combination of these two approaches. Experimental investigation and computational simulations are applied for the performance assessments. The experiments are carried out in the Axial Flow Turbine Research Facility (AFTRF) having a diameter of 91.66cm. The NGV exit flow structure was examined under the influence of a 29 bladed high pressure turbine rotor assembly operating at 1300 rpm. For the experimental measurement comparison, a reference Flat Insert endwall is installed in the nozzle guide vane (NGV) passage. It has a constant thickness with a cylindrical surface and is manufactured by a stereolithography (SLA) method. Four different LE fillets are designed, and they are attached to both cylindrical Flat Insert and the contoured endwall. Total pressure measurements are taken at rotor inlet plane with Kiel probe. The probe traversing is completed with one vane pitch and from 8% to 38% span. For one of the designs, area averaged loss is reduced by 15.06%. The simulation estimated this reduction as 7.11%. Computational evaluation is performed with the rotating domain and the rim seal flow between the NGV and the rotor blades. The most effective design reduced the mass averaged loss by 1.28% over the whole passage at the NGV exit.

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Generation Mechanism of Broadband Whoosh Noise in an Automotive Turbocharger Centrifugal Compressor

Journal of Turbomachinery ◽

10.1115/1.4051274 ◽

2021 ◽

pp. 1-35

Author(s):

Rick Dehner ◽

Pranav Sriganesh ◽

Ahmet Selamet ◽

Keith Miazgowicz

Keyword(s):

Centrifugal Compressor ◽

Combustion Engine ◽

Three Dimensional ◽

Leading Edge ◽

Broadband Noise ◽

Rotor Blades ◽

Generation Mechanism ◽

Primary Concern ◽

Frequency Range ◽

Modal Decomposition

Abstract The present study focuses on the acoustics of a turbocharger centrifugal compressor from a spark-ignition internal combustion engine. Whoosh noise is typically the primary concern for this type of compressor, which is loosely characterized by broadband sound elevation in the 4 to 13 kHz range. To identify the generation mechanism of broadband whoosh noise, the present study combines three approaches: three-dimensional (3D) computational fluid dynamics (CFD) predictions, experiments, and modal decomposition of 3D CFD results. After establishing the accuracy of predictions, flow structures and time-resolved pressures are closely examined in the vicinity of the main blade leading edge. This reveals the presence of rotating instabilities that may interact with the rotor blades to generate noise. An azimuthal modal decomposition is performed on the predicted pressure field to determine the number of cells and the frequency content of these rotating instabilities. The strength of the rotating instabilities and the frequency range in which noise is generated as a consequence of the rotor-rotating instability interaction, is found to correspond well with the qualitative trend of the whoosh noise that is measured several duct diameters upstream of the rotor blades. The variation of whoosh frequency range between low and high rotational speeds is interpreted through this analysis. It is also found that the whoosh noise primarily propagates along the duct as acoustic azimuthal modes. Hence, the inlet duct diameter, which governs the cut-off frequency for multi-dimensional acoustic modes, determines the lower frequency bound of the broadband noise.

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Vibrations of a Helicopter Rotor-Fuselage System Induced by the Main Rotor Blades in Flight

Journal of Applied Mechanics ◽

10.1115/1.4011086 ◽

1955 ◽

Vol 22 (3) ◽

pp. 355-360

Author(s):

M. Morduchow ◽

S. W. Yuan ◽

H. Reissner

Keyword(s):

Theoretical Analysis ◽

Natural Frequencies ◽

Rotor Blades ◽

Helicopter Rotor ◽

Simplified Model ◽

Main Rotor ◽

Numerical Examples ◽

The Masses

Abstract Based on a simplified model of the hub-fuselage structure, a theoretical analysis is made of the response of the hub and fuselage of a helicopter in flight to harmonic forces transmitted by the rotor blades to the hub both in, and normal to, the plane of rotation. The assumed structure is in the form of a plane framework with masses concentrated at the joints. Simple expressions are derived for the vibration amplitudes of the mass points as functions of the masses and natural frequencies of the hub and the fuselage. The pertinent nondimensional parameters are determined, and simple explicit conditions of resonance are derived. Numerical examples are given to illustrate the results.

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MATHEMATICAL MODELS OF THE RADAR SIGNAL REFLECTED FROM A HELICOPTER MAIN ROTOR IN APPLICATION TO INVERSE SYNTHESIS OF ANTENNA APERTURE

Journal of the Russian Universities Radioelectronics ◽

10.32603/1993-8985-2019-22-3-74-87 ◽

2019 ◽

Vol 22 (3) ◽

pp. 74-87 ◽

Cited By ~ 1

Author(s):

Sergey R. Heister ◽

Thai T. Nguyn

Keyword(s):

Mathematical Models ◽

Vertical Plane ◽

Rotor Blades ◽

Radar Signal ◽

Main Rotor ◽

Antenna Aperture ◽

Radar Images ◽

Aerial Vehicles ◽

Propeller Blades ◽

Helicopter Main Rotor

Introduction. The basis for solving the problem of aircraft recognition is the formation of radar portraits, reflecting the constructive features of aerial vehicles. Portraits, which are radar images of the propellers of aerial vehicles, have high informativeness. These images allow us to distinguish the number and relative position of the propeller blades, as well as the direction of its rotation. The basis for obtaining such images are mathematical models of reflected signals. Objective. The aim of this paper is to develop mathematical models of the radar signal reflected from the helicopter main rotor applied to inverse synthetic aperture radar (ISAR). Methods and materials. ISAR processing is used to produce a radar image of a propeller in a radar with a monochromatic probing signal. The propeller blades in the models are approximated by different geometric shapes. The models used to describe the reflection from the propellers of helicopters and fixed-wing aircraft have significant differences. In the process of moving each blade of the helicopter main rotor makes characteristic movements (flapping, dragging, feathering), as well as bends in a vertical plane. Such movements and bendings of the blades are influence the phase of the signal reflected from the main rotor. It is necessary to take the phase change of the reflected signal into account as accurately as possible when developing an ISAR algorithm for imaging the main rotor. Results. We found that in the centimeter wavelength range the mathematical model of the signal reflected from the helicopter main rotor as a system of blades is most accurately described by representing each blade with a set of isotropic reflectors located on the main rotor’s blade leading and trailing edges. Taking into account the flapping movements and curved shapes of the blades in the model allows you to get as close as possible to the features of the real signal. Conclusion. The developed model which takes into account the flapping movements and bends of the helicopter main rotor blades can be used to improve the ISAR algorithms providing the radar imaging of aerial vehicles.

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Experimental Characterization of Leading Edge Tubercles on Rotor Blades

10.2514/6.2022-1966 ◽

2022 ◽

Author(s):

Ryley R. Colpitts ◽

Dillon Hesketh ◽

Ruben E. Perez

Keyword(s):

Leading Edge ◽

Rotor Blades ◽

Experimental Characterization

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MEASUREMENT PROGRAM TO DETERMINE STATIC ELECTRICITY CHARGING CURRENTS IN HELICOPTER MAIN ROTOR BLADES

10.21236/ad0605828 ◽

1964 ◽

Author(s):

Samuel Baron ◽

Edward Cholakian ◽

Thomas M. Coonan

Keyword(s):

Rotor Blades ◽

Static Electricity ◽

Main Rotor ◽

Helicopter Main Rotor

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Effect of Leading-Edge Tubercles on Rotor Blades

AIAA AVIATION 2020 FORUM ◽

10.2514/6.2020-2763 ◽

2020 ◽

Author(s):

Robert R. Colpitts ◽

Ruben E. Perez ◽

Peter W. Jansen

Keyword(s):

Leading Edge ◽

Rotor Blades

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Aerodynamic Detuning Analysis of an Unstalled Supersonic Turbofan Cascade

Journal of Engineering for Gas Turbines and Power ◽

10.1115/1.3239886 ◽

1986 ◽

Vol 108 (1) ◽

pp. 60-67 ◽

Cited By ~ 6

Author(s):

D. Hoyniak ◽

S. Fleeter

Keyword(s):

Flow Field ◽

Leading Edge ◽

Rotor Blades ◽

Driving Mechanism ◽

Aeroelastic Stability ◽

Aerodynamic Forces ◽

Unsteady Aerodynamic ◽

Influence Coefficients ◽

Blade Row ◽

The Stability

A new, and as yet unexplored, approach to passive flutter control is aerodynamic detuning, defined as designed passage-to-passage differences in the unsteady aerodynamic flow field of a rotor blade row. Thus, aerodynamic detuning directly affects the fundamental driving mechanism for flutter, i.e., the unsteady aerodynamic forces and moments acting on individual rotor blades. In this paper, a model to demonstrate the enhanced supersonic unstalled aeroelastic stability associated with aerodynamic detuning is developed. The stability of an aerodynamically detuned cascade operating in a supersonic inlet flow field with a subsonic leading edge locus is analyzed, with the aerodynamic detuning accomplished by means of nonuniform circumferential spacing of adjacent rotor blades. The unsteady aerodynamic forces and moments on the blading are defined in terms of influence coefficients in a manner that permits the stability of both a conventional uniformly spaced rotor configuration as well as the detuned nonuniform circumferentially spaced rotor to be determined. With Verdon’s uniformly spaced Cascade B as a baseline, this analysis is then utilized to demonstrate the potential enhanced aeroelastic stability associated with this particular type of aerodynamic detuning.

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The Effect of Variable Chord Length on Transonic Axial Rotor Performance

Journal of Turbomachinery ◽

10.1115/1.1459734 ◽

2002 ◽

Vol 124 (3) ◽

pp. 351-357 ◽

Cited By ~ 8

Author(s):

William B. Roberts ◽

Albert Armin ◽

George Kassaseya ◽

Kenneth L. Suder ◽

Scott A. Thorp ◽

...

Keyword(s):

Leading Edge ◽

Aerodynamic Performance ◽

Chord Length ◽

Rotor Blades ◽

Civil Aviation ◽

Turbofan Engines ◽

Transonic Compressor ◽

Compressor Rotor ◽

Significant Difference ◽

Leading Edges

Aircraft fan and compressor blade leading edges suffer from atmospheric particulate erosion that reduces aerodynamic performance. Recontouring the blade leading edge region can restore blade performance. This process typically results in blades of varying chord length. The question therefore arises as to whether performance of refurbished fans and compressors could be further improved if blades of varying chord length are installed into the disk in a certain order. To investigate this issue the aerodynamic performance of a transonic compressor rotor operating with blades of varying chord length was measured in back-to-back compressor test rig entries. One half of the rotor blades were the full nominal chord length while the remaining half of the blades were cut back at the leading edge to 95% of chord length and recontoured. The rotor aerodynamic performance was measured at 100, 80, and 60% of design speed for three blade installation configurations: nominal-chord blades in half of the disk and short-chord blades in half of the disk; four alternating quadrants of nominal-chord and short-chord blades; nominal-chord and short-chord blades alternating around the disk. No significant difference in performance was found between configurations, indicating that blade chord variation is not important to aerodynamic performance above the stall chord limit if leading edges have the same shape. The stall chord limit for most civil aviation turbofan engines is between 94–96% of nominal (new) blade chord.

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