A fast simple hot-wire method of determining the mean velocity vector of complex three-dimensional flows

An explicit non-real time method of reducing triple sensor hot-wire anenometer data to obtain the three mean velocity components and six Reynolds stresses, as well as their turbulence spectra in three-dimensional flow is proposed. Equations which relate explicitly the mean velocity components and Reynolds stresses in laboratory coordinates to the mean and mean square sensors output voltages in three stages are derived. The method was verified satisfactorily by comparison with single sensor hot-wire anemometer measurements in a zero pressure gradient incompressible turbulent boundary layer flow. It is simple and requires much lesser computation time when compared to other implicit non-real time method.

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Turbulence Measurements Near the Stern of a Ship Model

Journal of Ship Research ◽

10.5957/jsr.1984.28.3.186 ◽

1984 ◽

Vol 28 (03) ◽

pp. 186-201

Author(s):

Lennart Löfdahl ◽

Lars Larsson

Keyword(s):

Boundary Layer ◽

Strong Influence ◽

Three Dimensional ◽

Reynolds Stresses ◽

Hot Wire ◽

Calculation Methods ◽

Mean Velocity ◽

Ship Model ◽

The Mean ◽

Stress Profiles

An experimental investigation in which Reynolds stress profiles were measured in the thick three-dimensional turbulent boundary layer at the stern of a ship model has been carried out. The measurements were performed using a specially developed hot-wire technique in which the mean velocity component perpendicular to the surface was considered. A large number of results are given in diagrams, and an error estimation for the different Reynolds stresses is presented. Efforts have been made, when positioning the measured turbulence profiles, to enable future development of calculation methods based on these results. The measured profiles have revealed a strong influence of streamline convergence (divergence) on the Reynolds stresses. Also, the effects of wall curvature are of importance, and since most parts of the investigated region have a convex curvature the average level of the stresses is reduced.

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Hot Wire Measurements at the Exit of a Centrifugal Compressor Impeller

Proceedings of the Institution of Mechanical Engineers ◽

10.1243/pime_proc_1979_193_037_02 ◽

1979 ◽

Vol 193 (1) ◽

pp. 341-347

Author(s):

A. Goulas ◽

R. C. Baker

Keyword(s):

Centrifugal Compressor ◽

Magnetic Tape ◽

Reynolds Stresses ◽

Hot Wire ◽

Mean Velocity ◽

Isentropic Flow ◽

Compressor Impeller ◽

The Mean

Hot wire measurements at the exit of a small centrifugal compressor impeller are reported. Three different hot wire readings were obtained and stored on a magnetic tape for each point by gating the analogue hot wire signal with a pulse which indicated circumferential position. The combination of the three readings yielded the mean velocity and some Reynolds stresses at each point. The measurements show a ‘jet-wake’ profile towards the shroud and ‘isentropic’ flow near the hub.

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Three-Dimensional Wake Decay Inside of a Compressor Cascade and its Influence on the Downstream Unsteady Flow Field: Part I — Wake Decay Characteristics in the Flow Passage

Volume 1: Turbomachinery ◽

10.1115/90-gt-021 ◽

1990 ◽

Cited By ~ 2

Author(s):

C. Poensgen ◽

H. E. Gallus

Keyword(s):

Flow Field ◽

Turbulent Flows ◽

Velocity Vector ◽

Three Dimensional ◽

Time Dependent ◽

Major Influence ◽

Hot Wire ◽

Compressor Cascade ◽

Flow Passage ◽

Turbulent Flow Field

A measuring technique based on multisensor hot-wire anemometry has been developed to determine the unsteady three-dimensional velocity vector and the structure of turbulent flows. It then has been applied to the passage and the exit flow of an annular compressor cascade, which is periodically disturbed by the wakes of a cylinder rotor, located about 50 percent of blade chord upstream. In part I of this paper the decay of the rotor wakes will be described first without stator and secondly through a stator passage. The time-dependent turbulent flow field downstream of this stator is discussed in Part II. The rotor wakes have a major influence on the development of three-dimensional separated regions inside the compressor cascade, and this interaction will be addressed in both parts of this paper.

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Turbulent Vorticity Diffusion in the Stronger Wall Jet Managed by a Flat Plate Wing in the Outer Layer

Volume 1A: Symposia, Part 2 ◽

10.1115/ajkfluids2015-25473 ◽

2015 ◽

Author(s):

Takuma Katayama ◽

Shinsuke Mochizuki

Keyword(s):

Shear Stress ◽

Flat Plate ◽

Outer Layer ◽

Large Scale ◽

Reynolds Shear Stress ◽

Three Dimensional ◽

Quantitative Relationship ◽

Wall Jet ◽

Mean Velocity ◽

The Mean

The present experiment focuses on the vorticity diffusion in a stronger wall jet managed by a three-dimensional flat plate wing in the outer layer. Measurement of the fluctuating velocities and vorticity correlation has been carried out with 4-wire vorticity probe. The turbulent vorticity diffusion due to the large scale eddies in the outer layer is quantitatively examined by using the 4-wire vorticity probe. Quantitative relationship between vortex structure and Reynolds shear stress is revealed by means of directly measured experimental evidence which explains vorticity diffusion process and influence of the manipulating wing. It is expected that the three-dimensional outer layer manipulator contributes to keep convex profile of the mean velocity, namely, suppression of the turbulent diffusion and entrainment.

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Measurements with a pulsed-wire and a hot-wire anemometer in the highly turbulent wake of a normal flat plate

Journal of Fluid Mechanics ◽

10.1017/s0022112076002218 ◽

1976 ◽

Vol 77 (3) ◽

pp. 473-497 ◽

Cited By ~ 71

Author(s):

L. J. S. Bradbury

Keyword(s):

Turbulent Flow ◽

Flat Plate ◽

Flow Direction ◽

Operating Conditions ◽

Turbulent Intensity ◽

Hot Wire ◽

Mean Flow ◽

Mean Velocity ◽

The Mean ◽

Better Than

This paper describes an investigation into the response of both the pulsed-wire anemometer and the hot-wire anemometer in a highly turbulent flow. The first part of the paper is concerned with a theoretical study of some aspects of the response of these instruments in a highly turbulent flow. It is shown that, under normal operating conditions, the pulsed-wire anemometer should give mean velocity and longitudinal turbulent intensity estimates to an accuracy of better than 10% without any restriction on turbulence level. However, to attain this accuracy in measurements of turbulent intensities normal to the mean flow direction, there is a lower limit on the turbulent intensity of about 50%. An analysis is then carried out of the behaviour of the hot-wire anemometer in a highly turbulent flow. It is found that the large errors that are known to develop are very sensitive to the precise structure of the turbulence, so that even qualitative use of hot-wire data in such flows is not feasible. Some brief comments on the possibility of improving the accuracy of the hot-wire anemometer are then given.The second half of the paper describes some comparative measurements in the highly turbulent flow immediately downstream of a normal flat plate. It is shown that, although it is not possible to interpret the hot-wire results on their own, it is possible to calculate the hot-wire response with a surprising degree of accuracy using the results from the pulsed-wire anemometer. This provides a rather indirect but none the less welcome check on the accuracy of the pulsed-wire results, which, in this very highly turbulent flow, have a certain interest in their own right.

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Intermittency measurements in the turbulent boundary layer

Journal of Fluid Mechanics ◽

10.1017/s0022112066000363 ◽

1966 ◽

Vol 25 (4) ◽

pp. 719-735 ◽

Cited By ~ 81

Author(s):

H. Fiedler ◽

M. R. Head

Keyword(s):

Boundary Layer ◽

Turbulent Boundary Layer ◽

Focal Point ◽

Pressure Gradients ◽

Narrow Beam ◽

Hot Wire ◽

Characteristic Parameters ◽

Mean Velocity ◽

Form Parameter ◽

The Mean

An improved version of Corrsin & Kistler's method has been used to measure intermittency in favourable and adverse pressure gradients, and the characteristic parameters of the intermittency have been related to the form parameterHof the mean velocity profiles.It is found that with adverse pressure gradients the centre of intermittency moves outward from the surface while the width of the intermittent zone decreases. The converse is true of favourable pressure gradients, and it seems likely that at sufficiently low values ofHthe flow over the full depth of the layer is only intermittently turbulent.A new method of intermittency measurement is presented which makes use of a photo-electric probe. Smoke is introduced into the boundary layer and illuminated by a narrow beam of parallel light normal to the surface. The photoelectric probe is focused on the illuminated region and a signal is generated when smoke passes through the focal point of the probe lens. Comparison of this signal with the output from a hot-wire at very nearly the same point shows the identity of smoke and turbulence distributions.

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Application of a Three-Dimensional Inverse Method to the Design of a Centrifugal Compressor Impeller

Volume 1: Turbomachinery ◽

10.1115/98-gt-127 ◽

1998 ◽

Cited By ~ 1

Author(s):

Alain Demeulenaere ◽

Olivier Léonard ◽

René Van den Braembussche

Keyword(s):

Centrifugal Compressor ◽

Inverse Method ◽

Three Dimensional ◽

Navier Stokes ◽

Centrifugal Impeller ◽

Mean Velocity ◽

Blade Shape ◽

Compressor Impeller ◽

Real Performance ◽

The Mean

The use of a three-dimensional Euler inverse method for the design of a centrifugal impeller is demonstrated. Both the blade shape and the endwalls are iteratively designed. The meridional contour is modified in order to control the mean velocity level in the blade channel, while the blade shape is designed to achieve a prescribed loading distribution between the inlet and the outlet. The method salves the time dependent Euler equations in a numerical domain of which some boundaries (the blades or the endwalls) move and change shape during the transient part of the computation, until a prescribed pressure distribution is achieved on the blade surfaces. The method is applied to the design of a centrifugal compressor impeller, whose hub endwall and blade surfaces are modified by the inviscid inverse method. The real performance of both initial and modified geometries are compared through three-dimensional Navier-Stokes computations.

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A three-dimensional turbulent boundary layer

Journal of Fluid Mechanics ◽

10.1017/s0022112065000757 ◽

1965 ◽

Vol 22 (2) ◽

pp. 285-304 ◽

Cited By ~ 25

Author(s):

A. E. Perry ◽

P. N. Joubert

Keyword(s):

Boundary Layer ◽

Turbulent Boundary Layer ◽

Three Dimensional ◽

Outer Part ◽

Outer Region ◽

Experimental Results ◽

Mean Velocity ◽

Polar Plot ◽

Law Of The Wall ◽

The Mean

The purpose of this paper is to provide some possible explantions for certain observed phenomena associated with the mean-velocity profile of a turbulent boundary layer which undergoes a rapid yawing. For the cases considered the yawing is caused by an obstruction attached to the wall upon which the boundary layer is developing. Only incompressible flow is considered.§1 of the paper is concerned with the outer region of the boundary layer and deals with a phenomenon observed by Johnston (1960) who described it with his triangular model for the polar plot of the velocity distribution. This was also observed by Hornung & Joubert (1963). It is shown here by a first-approximation analysis that such a behaviour is mainly a consequence of the geometry of the apparatus used. The analysis also indicates that, for these geometries, the outer part of the boundary-layer profile can be described by a single vector-similarity defect law rather than the vector ‘wall-wake’ model proposed by Coles (1956). The former model agrees well with the experimental results of Hornung & Joubert.In §2, the flow close to the wall is considered. Treating this region as an equilibrium layer and using similarity arguments, a three-dimensional version of the ‘law of the wall’ is derived. This relates the mean-velocity-vector distribution with the pressure-gradient vector and wall-shear-stress vector and explains how the profile skews near the wall. The theory is compared with Hornung & Joubert's experimental results. However at this stage the results are inconclusive because of the lack of a sufficient number of measured quantities.

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Combined effects of flow curvature and rotation on uniformly sheared turbulence

Journal of Fluid Mechanics ◽

10.1017/s0022112009006296 ◽

2009 ◽

Vol 628 ◽

pp. 371-394 ◽

Cited By ~ 1

Author(s):

D. C. ROACH ◽

A. G. L. HOLLOWAY

Keyword(s):

Shear Stress ◽

Wind Tunnel ◽

Model Development ◽

Three Dimensional ◽

Simple Shear Flow ◽

Test Case ◽

Mean Velocity ◽

Tunnel Section ◽

Flow Curvature ◽

The Mean

This paper describes an experiment in which a uniformly sheared turbulence was subjected to simultaneous streamwise flow curvature and rotation about the streamwise axis. The distortion of the turbulence is complex but well defined and may serve as a test case for turbulence model development. The uniformly sheared turbulence was developed in a straight wind tunnel and then passed into a curved tunnel section. At the start of the curved section the plane of the mean shear was normal to the plane of curvature so as to create a three-dimensional or ‘out of plane’ curvature configuration. On entering the curved tunnel, the flow developed a streamwise mean vorticity that rotated the mean shear about the tunnel centreline through approximately 70°, so that the shear was nearly in the plane of curvature and oriented so as to have a stabilizing effect on the turbulence. Hot wire measurements of the mean velocity, mean vorticity, mean rate of strain and Reynolds stress anisotropy development along the wind tunnel centreline are reported. The observed effect of the mean shear rotation on the turbulence was to diminish the shear stress in the plane normal to the plane of curvature while generating non-zero values of the shear stress in the plane of curvature. A rotating frame was identified for which the measured mean velocity field took the form of a simple shear flow. The turbulence anisotropy was transformed to this frame to estimate the effects of frame rotation on the structure of sheared turbulence.

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