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References (27)
-
C. Koning (1935)
Influence of the Propeller on Other Parts of the Airplane Structure -
J. Kalogiros, Qing Wang (2002)
Calibration of a Radome-Differential GPS System on a Twin Otter Research Aircraft for Turbulence MeasurementsJournal of Atmospheric and Oceanic Technology, 19
-
(1958)
The response of an airplane to random atmospheric turbulence -
M. Tjernström, C. Friehe (1991)
Analysis of a Radome Air-Motion System on a Twin-Jet Aircraft for Boundary-Layer ResearchJournal of Atmospheric and Oceanic Technology, 8
-
P. Durand, L. Sá, A. Druilhet, F. Saïd (1991)
Use of the Inertial Dissipation Method for Calculating Turbulent Fluxes from Low-Level Airborne MeasurementsJournal of Atmospheric and Oceanic Technology, 8
-
S. Nicholls, C. Readings (1981)
Spectral characteristics of surface layer turbulence over the seaQuarterly Journal of the Royal Meteorological Society, 107
-
H. Norment, A. Quealy, R. Shaw (1988)
Three-dimensional trajectory analyses of two drop sizing instruments - PMS OAP and PMS FSSP. [Optical Array Probe and Forward Scattering Spectrometer Probe -
T. Crawford, R. Dobosy, E. Dumas (1996)
Aircraft wind measurement considering lift-induced upwashBoundary-Layer Meteorology, 80
-
D. Khelif, S. Burns, C. Friehe (1999)
Improved Wind Measurements on Research AircraftJournal of Atmospheric and Oceanic Technology, 16
-
T. Crawford, R. Dobosy (1992)
A sensitive fast-response probe to measure turbulence and heat flux from any airplaneBoundary-Layer Meteorology, 59
-
R. Bisplinghoff, H. Ashley, M. Goland (1975)
Principles of aeroelasticity -
A. Drummond, J. MacPherson (1985)
Aircraft Flow Effects on Cloud Drop Images and Concentrations Measured by the NAE Twin OtterJournal of Atmospheric and Oceanic Technology, 2
-
L. Kristensen, N. Jensen (1979)
Lateral coherence in isotropic turbulence and in the natural windBoundary-Layer Meteorology, 17
-
N. Piercy (1979)
Aerodynamics for Engineers -
D. Lenschow, E. Miller, R. Friesen (1991)
A Three-Aircraft Intercomparison of Two Types of Air Motion Measurement SystemsJournal of Atmospheric and Oceanic Technology, 8
-
R. Jones (1940)
The unsteady lift of a wing of finite aspect ratio -
J. Katz, A. Plotkin (1991)
Low-Speed Aerodynamics -
H. Okubo, M. Kobayakawa, H. Maéda (1979)
Lifting Surface Approach to the Estimation of Gust Response of Finite WingsJournal of Aircraft, 16
-
J., R. Hunt (1973)
A theory of turbulent flow round two-dimensional bluff bodiesJournal of Fluid Mechanics, 61
-
W. Bögel, R. Baumann (1991)
Test and Calibration of the DLR Falcon Wind Measuring System by ManeuversJournal of Atmospheric and Oceanic Technology, 8
-
P. Mason (1995)
Atmospheric boundary layer flows: Their structure and measurementBoundary-Layer Meteorology, 72
-
R. Shevell (1983)
Fundamentals of Flight -
D. Lenschow (1986)
Aircraft measurements in the boundary layer -
(1985)
1985: Wind tunnel investigation of the interaction of propeller slipstream with nacelle/flap -
A. Williams, D. Marcotte (2000)
Wind Measurements on a Maneuvering Twin-Engine Turboprop Aircraft Accounting for Flow DistortionJournal of Atmospheric and Oceanic Technology, 17
-
H. Norment, A. Quealy, R. Shaw (1987)
Three-dimensional trajectory analyses of two drop sizing instruments- PMS OAP and PMS FSSP -
L. Filotas (1971)
Approximate transfer functions for large aspect ratio wings in turbulent flowJournal of Aircraft, 8
- Publisher
- American Meteorological Society
- Copyright
- Copyright © 2001 American Meteorological Society
- ISSN
- 1520-0426
- DOI
- 10.1175/1520-0426(2002)019<1567:AEOWTM>2.0.CO;2
- Publisher site
- See Article on Publisher Site
Abstract
Flow distortion is a major issue in the measurement of wind turbulence with gust probes mounted on a nose boom, at the radome, or under the wing of research aircraft. In this paper, the effects both of the propellers of a turboprop aircraft and of the aircraft vortex system on the pressure and wind velocity measurements near the nose of the aircraft are examined. It is shown that, for a turboprop aircraft, the sensors mounted near the nose are affected directly (slipstream) or indirectly (lift increase) by the propellers. The propeller effects are more significant for pressure sensors located ahead of the propellers on the fuselage and are less significant for the small local flow angles measured at the nose of the aircraft. The first case is clearly realized during in-flight calibration maneuvers performed by a turboprop aircraft. A major flow distortion, which seriously affects the vertical wind velocity measurements near the nose of an aircraft, is the upwash induced mainly by the wing-bound vortex. Also, low energy of the vertical wind component in the inertial subrange for scales larger than the fuselage diameter is usually observed in aircraft measurements. This is shown to be the result of not taking into account the decrease of the upwash correction with eddy frequency (or no need for such a correction in the inertial subrange) caused by the aerodynamic delay and the response of the wing vortex to turbulence. The level of energy in the inertial subrange of the vertical wind component is significant because it is commonly used for the estimation of the dissipation rate of turbulence kinetic energy. A method to estimate this frequency variable correction and correct the spectra or the time series of the estimated vertical wind component is described. Data from low-level flight legs with a Twin Otter aircraft show that this correction may result in about a 20%% correction of the variance of the vertical wind component and a 5%% correction of the vertical turbulent fluxes.
Journal
Journal of Atmospheric and Oceanic Technology – American Meteorological Society
Published: May 1, 2001