Some Characteristics of Cavity Flow Past Cylindrical Inducers in a Venturi

B. C. Syamala Rao; D. V. Chandrasekhara

doi:10.1115/1.3448368

Strouhal Number for VIV Excitation of Long Slender Structures

Volume 5: Pipelines, Risers, and Subsea Systems ◽

10.1115/omae2018-77433 ◽

2018 ◽

Author(s):

Andrew E. Potts ◽

Douglas A. Potts ◽

Hayden Marcollo ◽

Kanishka Jayasinghe

Keyword(s):

Reynolds Number ◽

Strouhal Number ◽

Degrees Of Freedom ◽

Measurement Techniques ◽

Cross Flow ◽

Degree Of Freedom ◽

Circular Cylinders ◽

Two Degrees Of Freedom ◽

Shedding Frequency ◽

Eddy Shedding

The prediction of Vortex-Induced Vibration (VIV) of cylinders under fluid flow conditions depends upon the eddy shedding frequency, conventionally described by the Strouhal Number. The most commonly cited relationship between Strouhal Number and Reynolds Number for circular cylinders was developed by Lienhard [1], whereby the Strouhal Number exhibits a consistent narrow band of about 0.2 (conventional across the sub-critical Re range), with a pronounced hump peaking at about 0.5 within the critical flow regime. The source data underlying this relationship is re-examined, wherein it was found to be predominantly associated with eddy shedding frequency about fixed or stationary cylinders. The pronounced hump appears to be an artefact of the measurement techniques employed by various investigators to detect eddy-shedding frequency in the wake of the cylinder. A variety of contemporary test data for elastically mounted cylinders, with freedom to oscillate under one degree of freedom (i.e. cross flow) and two degrees of freedom (i.e. cross flow and in-line) were evaluated and compared against the conventional Strouhal Number relationship. It is well established for VIV that the eddy shedding frequency will synchronise with the near resonant motions of a dynamically oscillating cylinder, such that the resultant bandwidth of lock-in exhibits a wider range of effective Strouhal Numbers than that reflected in the narrow-banded relationship about a mean of 0.2. However, whilst cylinders oscillating under one degree of freedom exhibit a mean Strouhal Number of 0.2 consistent with fixed/stationary cylinders, cylinders with two degrees of freedom exhibit a much lower mean Strouhal Number of around 0.14–0.15. Data supports the relationship that Strouhal Number does slightly diminish with increasing Reynolds Number. For oscillating cylinders, the bandwidth about the mean Strouhal Number value appears to remain largely consistent. For many practical structures in the marine environment subject to VIV excitation, such as long span, slender risers, mooring lines, pipeline spans, towed array sonar strings, and alike, the long flexible cylinders will respond in two degrees of freedom, where the identified difference in Strouhal Number is a significant aspect to be accounted for in the modelling of its dynamic behaviour.

Download Full-text

Flow past a rotationally oscillating cylinder

Journal of Fluid Mechanics ◽

10.1017/jfm.2013.469 ◽

2013 ◽

Vol 735 ◽

pp. 307-346 ◽

Cited By ~ 25

Author(s):

S. Kumar ◽

C. Lopez ◽

O. Probst ◽

G. Francisco ◽

D. Askari ◽

...

Keyword(s):

Reynolds Number ◽

Vortex Shedding ◽

Three Dimensional ◽

Far Field ◽

Two Dimensional ◽

Flow Past ◽

Vortex Shedding Frequency ◽

Shedding Frequency ◽

Flow Visualizations ◽

Hydrogen Bubble Technique

AbstractFlow past a circular cylinder executing sinusoidal rotary oscillations about its own axis is studied experimentally. The experiments are carried out at a Reynolds number of 185, oscillation amplitudes varying from $\mathrm{\pi} / 8$ to $\mathrm{\pi} $, and at non-dimensional forcing frequencies (ratio of the cylinder oscillation frequency to the vortex-shedding frequency from a stationary cylinder) varying from 0 to 5. The diagnostic is performed by extensive flow visualization using the hydrogen bubble technique, hot-wire anemometry and particle-image velocimetry. The wake structures are related to the velocity spectra at various forcing parameters and downstream distances. It is found that the phenomenon of lock-on occurs in a forcing frequency range which depends not only on the amplitude of oscillation but also the downstream location from the cylinder. The experimentally measured lock-on diagram in the forcing amplitude and frequency plane at various downstream locations ranging from 2 to 23 diameters is presented. The far-field wake decouples, after the lock-on at higher forcing frequencies and behaves more like a regular Bénard–von Kármán vortex street from a stationary cylinder with vortex-shedding frequency mostly lower than that from a stationary cylinder. The dependence of circulation values of the shed vortices on the forcing frequency reveals a decay character independent of forcing amplitude beyond forcing frequency of ${\sim }1. 0$ and a scaling behaviour with forcing amplitude at forcing frequencies ${\leq }1. 0$. The flow visualizations reveal that the far-field wake becomes two-dimensional (planar) near the forcing frequencies where the circulation of the shed vortices becomes maximum and strong three-dimensional flow is generated as mode shape changes in certain forcing parameter conditions. It is also found from flow visualizations that even at higher Reynolds number of 400, forcing the cylinder at forcing amplitudes of $\mathrm{\pi} / 4$ and $\mathrm{\pi} / 2$ can make the flow field two-dimensional at forcing frequencies greater than ${\sim }2. 5$.

Download Full-text

Numerical Study of Flow Characteristics Around Confined Cylinder using OpenFOAM

International Journal of Engineering & Technology ◽

10.14419/ijet.v7i4.35.22925 ◽

2018 ◽

Vol 7 (4.35) ◽

pp. 617

Author(s):

P. Mathupriya ◽

L. Chan ◽

H. Hasini ◽

A. Ooi

Keyword(s):

Reynolds Number ◽

Vortex Shedding ◽

Numerical Study ◽

Vortex Formation ◽

Plane Channel ◽

Flow Characteristics ◽

Strong Interactions ◽

Two Dimensional ◽

Computational Fluid Dynamics Cfd ◽

Shedding Frequency

The numerical study of the flow over a two-dimensional cylinder which is symmetrically confined in a plane channel is presented to study the characteristics of vortex shedding. The numerical model has been established using direct numerical simulation (DNS) based on the open source computational fluid dynamics (CFD) code named OpenFOAM. In the present study, the flow fields have been computed at blockage ratio, β of 0.5 and at Reynolds number, Re of 200 and 300. Two-dimensional simulations investigated on the effects of Reynolds number based on the vortex formation and shedding frequency. It was observed that the presence of two distinct shedding frequencies appear at higher Reynolds number due to the confinement effects where there is strong interactions between boundary layer, shear layer and the wake of the cylinder. The range of simulations conducted here has shown to produce results consistent with that available in the open literature. Therefore, OpenFOAM is found to be able to accurately capture the complex physics of the flow.

Download Full-text

The transition from sheet to cloud cavitation

Journal of Fluid Mechanics ◽

10.1017/jfm.2017.75 ◽

2017 ◽

Vol 817 ◽

pp. 439-454 ◽

Cited By ~ 25

Author(s):

P. F. Pelz ◽

T. Keil ◽

T. F. Groß

Keyword(s):

Reynolds Number ◽

Cavitation Number ◽

Wall Friction ◽

Bubble Collapse ◽

Penetration Length ◽

Cloud Cavitation ◽

Viscous Film ◽

History Of ◽

Good Agreement

Recent studies indicate that the transition from sheet to cloud cavitation depends on both cavitation number and Reynolds number. In the present paper this transition is investigated analytically and a physical model is introduced. In order to include the entire process, the model consists of two parts, a model for the growth of the sheet cavity and a viscous film flow model for the so-called re-entrant jet. The models allow the calculation of the length of the sheet cavity for given nucleation rates and initial nuclei radii and the spreading history of the viscous film. By definition, the transition occurs when the re-entrant jet reaches the point of origin of the sheet cavity, implying that the cavity length and the penetration length of the re-entrant jet are equal. Following this criterion, a stability map is derived showing that the transition depends on a critical Reynolds number which is a function of cavitation number and relative surface roughness. A good agreement was found between the model-based calculations and the experimental measurements. In conclusion, the presented research shows the evidence of nucleation and bubble collapse for the growth of the sheet cavity and underlines the role of wall friction for the evolution of the re-entrant jet.

Download Full-text

Transverse Oscillations of a Jet in a Jet-Splitter System

Journal of Basic Engineering ◽

10.1115/1.3425524 ◽

1972 ◽

Vol 94 (3) ◽

pp. 675-681 ◽

Cited By ~ 4

Author(s):

D. O. Rockwell

Keyword(s):

Reynolds Number ◽

Strouhal Number ◽

Nozzle Exit ◽

Reynolds Numbers ◽

Dimensionless Frequency ◽

Two Dimensional ◽

Vena Contracta ◽

Wide Range ◽

Jet Behavior ◽

Transverse Oscillations

The fundamental transverse oscillations of a liquid jet which impinged upon a flow splitter were examined for a wide range of dimensionless splitter distance, nozzle exit Reynolds number, and dimensionless frequency. The results are presented in the form of a design map. The data, taken at low nozzle aspect ratio, reveal that fundamental (stage 1) oscillations can exist for Reynolds numbers up to at least 7000. Up to Reynolds numbers of about 3000, the jet behavior is Reynolds number dependent for all values of splitter distance. Beyond Reynolds number of 3000 the jet behavior is independent of Reynolds number. In general, the Strouhal number, based on nozzle exit-splitter distance, decreases with increasing values of splitter distance. Jets issuing from nozzles with no parallel development sections were considered. Jet nozzle shape influences the dimensionless frequency of oscillation in that the effect of a vena contracta formation outside the nozzle exit is to yield a higher value of dimensionless frequency relative to nozzles which produce parallel flow with small boundary layer thickness at the exit. Similar decreases have been found for two-dimensional jets. Of the above findings, the only comparable results for two-dimensional jets are variations in Strouhal number with nozzle exit-splitter distance.

Download Full-text

Vortex growth in jets

Journal of Fluid Mechanics ◽

10.1017/s0022112070001714 ◽

1970 ◽

Vol 44 (1) ◽

pp. 97-112 ◽

Cited By ~ 81

Author(s):

Gordon S. Beavers ◽

Theodore A. Wilson

Keyword(s):

Reynolds Number ◽

Strouhal Number ◽

Computer Experiments ◽

Vortex Rings ◽

Periodic Flow ◽

Two Dimensional ◽

Vortex Sheets ◽

Vortex Pairs ◽

Symmetric Pattern ◽

Circular Orifice

Observations are reported on the growth of vortices in the vortex sheets bounding the jet emerging from a sharp-edged two-dimensional slit and from a sharp-edged circular orifice. A regular periodic flow is observed near the orifice for both configurations when the Reynolds number of the jet lies between about 500 and 3000. The two-dimensional jet produces a symmetric pattern of vortex pairs with a Strouhal number of 0·43. Vortex rings are formed in the circular jet with a Strouhal number of 0·63. Computer experiments show that a growing pair of vortices in two parallel vortex sheets produces a symmetric pattern of vortices upstream from the original disturbance.

Download Full-text

The onset of unsteadiness of two-dimensional bodies falling or rising freely in a viscous fluid: a linear study

Journal of Fluid Mechanics ◽

10.1017/jfm.2011.419 ◽

2011 ◽

Vol 690 ◽

pp. 173-202 ◽

Cited By ~ 15

Author(s):

Pauline Assemat ◽

David Fabre ◽

Jacques Magnaudet

Keyword(s):

Reynolds Number ◽

Viscous Fluid ◽

Strouhal Number ◽

Cross Section ◽

Vortex Shedding ◽

The Body ◽

Mode Switching ◽

Two Dimensional ◽

Body Dynamics ◽

Mass Ratios

AbstractWe consider the transition between the steady vertical path and the oscillatory path of two-dimensional bodies moving under the effect of buoyancy in a viscous fluid. Linearization of the Navier–Stokes equations governing the flow past the body and of Newton’s equations governing the body dynamics leads to an eigenvalue problem, which is solved numerically. Three different body geometries are then examined in detail, namely a quasi-infinitely thin plate, a plate of rectangular cross-section with an aspect ratio of 8, and a rod with a square cross-section. Two kinds of eigenmodes are observed in the limit of large body-to-fluid mass ratios, namely ‘fluid’ modes identical to those found in the wake of a fixed body, which are responsible for the onset of vortex shedding, and four additional ‘aerodynamic’ modes associated with much longer time scales, which are also predicted using a quasi-static model introduced in a companion paper. The stability thresholds are computed and the nature of the corresponding eigenmodes is investigated throughout the whole possible range of mass ratios. For thin bodies such as a flat plate, the Reynolds number characterizing the threshold of the first instability and the associated Strouhal number are observed to be comparable with those of the corresponding fixed body. Other modes are found to become unstable at larger Reynolds numbers, and complicated branch crossings leading to mode switching are observed. On the other hand, for bluff bodies such as a square rod, two unstable modes are detected in the range of Reynolds number corresponding to wake destabilization. For large enough mass ratios, the leading mode is similar to the vortex shedding mode past a fixed body, while for smaller mass ratios it is of a different nature, with a Strouhal number about half that of the vortex shedding mode and a stronger coupling with the body dynamics.

Download Full-text

Hydrodynamic Trends for Preliminary Design of Fully Cavitating Hydrofoil Sections

Marine Technology and SNAME News ◽

10.5957/mt1.1977.14.1.70 ◽

1977 ◽

Vol 14 (01) ◽

pp. 70-85

Author(s):

Blaine R. Parkin ◽

Robert F. Davis ◽

Joseph Fernandez

Keyword(s):

Pressure Distribution ◽

Lift Coefficient ◽

Flow Theory ◽

Cavity Flow ◽

Cavitation Number ◽

Viscous Drag ◽

Preliminary Design ◽

Two Dimensional ◽

Cavity Thickness ◽

Cavitating Hydrofoil

The object of this numerical study is to consider possible hydrodynamic trends for use in trade-off studies for the preliminary design of fully cavitating hydrofoil sections. Hydrodynamic data are obtained from inverse calculations which are based upon two-dimensional linearized cavity-flow theory. Supplementary data are also calculated from the direct problem of linearized cavity-flow theory in order to show off-design performance trends and to assess the effects of cavity-foil interference on the operating range of selected profiles. For the inverse calculations one specifies design values of the lift coefficient, cavitation number, and cavity thickness at the trailing edge, as well as the shape of the pressure distribution on the wetted surface of the hydrofoil section. In accordance with this specification, the ordinates of the profile wetted surface and upper-cavity contour are calculated, together with values of drag coefficient, moment coefficient, and attack angle at the design point. The paper summarizes the results of a parametric study of the effects of design cavitation number, lift coefficient, cavity thickness, and pressure distribution shape upon hydrofoil section performance and geometry. Three-dimensional wing effects, viscous drag, and the effects of structural design criteria are all outside the scope of the study. Results pertaining to steady two-dimensional cavity flows of an ideal incompressible fluid past a rigid hydrofoil section are presented.

Download Full-text

Two-Dimensional Computation for Aerodynamic Characteristics of Two Circular Cylinders in Tandem Arrangement at High Reynolds Number

The Proceedings of The Computational Mechanics Conference ◽

10.1299/jsmecmd.2004.17.383 ◽

2004 ◽

Vol 2004.17 (0) ◽

pp. 383-384

Author(s):

Norio KONDO

Keyword(s):

Reynolds Number ◽

High Reynolds Number ◽

Aerodynamic Characteristics ◽

Circular Cylinders ◽

Two Dimensional ◽

Tandem Arrangement ◽

High Reynolds

Download Full-text

Cavity-flow wall effects and correction rules

Journal of Fluid Mechanics ◽

10.1017/s0022112071002039 ◽

1971 ◽

Vol 49 (2) ◽

pp. 223-256 ◽

Cited By ~ 19

Author(s):

T. Yao-Tsu Wu ◽

Arthur K. Whitney ◽

Christopher Brennen

Keyword(s):

Drag Coefficient ◽

Theoretical Models ◽

Cavity Flow ◽

Cavitation Number ◽

The Body ◽

Wall Effects ◽

Flow Models ◽

Flow Parameters ◽

Spacing Ratio ◽

Wake Model

This paper is intended to evaluate the wall effects in the pure-drag case of plane cavity flow past an arbitrary body held in a closed tunnel, and to establish an accurate correction rule. The three theoretical models in common use, namely, the open-wake, Riabouchinsky and re-entrant-jet models, are employed to provide solutions in the form of some functional equations. From these theoretical solutions several different rules for the correction of wall effects are derived for symmetric wedges. These simple correction rules are found to be accurate, as compared with their corresponding exact numerical solutions, for all wedge angles and for small to moderate ‘tunnel-spacing ratio’ (the ratio of body frontal width to tunnel spacing). According to these correction rules, conversion of a drag coefficient, measured experimentally in a closed tunnel, to the corresponding unbounded flow case requires only the data of the conventional cavitation number and the tunnel-spacing ratio if based on the open-wake model, though using the Riabouchinsky model it requires an additional measurement of the minimum pressure along the tunnel wall.The numerical results for symmetric wedges show that the wall effects in-variably result in a lower drag coefficient than in an unbounded flow at the same cavitation number, and that this percentage drag reduction increases with decreasing wedge angle and/or with decreasing tunnel spacing relative to the body frontal width. This indicates that the wall effects axe generally more significant for thinner bodies in cavity flows, and they become exceedingly small for sufficiently blunt bodies. Physical explanations for these remarkable features of cavity-flow wall effects are sought; they are supported by the present experimental investigation of the pressure distribution on the wetted body surface as the flow parameters are varied. It is also found that the theoretical drag coefficient based on the Riabouchinsky model is smaller than that predicted by the open-wake model, all the flow parameters being equal, except when the flow approaches the choked state (with the cavity becoming infinitely long in a closed tunnel), which is the limiting case common to all theoretical models. This difference between the two flow models becomes especially pronounced for smaller wedge angles, shorter cavities, and with tunnel walls farther apart.In order to gauge the degree of accuracy of these theoretical models in approximating the real flows, and t o ascertain the validity of the correction rules, a series of definitive experiments was carefully designed to complement the theory, and then carried out in a high-speed water tunnel. The measurements on a series of fully cavitating wedges at zero incidence suggest that, of the theoretical models, that due to Riabouchinsky is superior throughout the range tested. The accuracy of the correction rule based on that model has also been firmly established. Although the experimental investigation has been limited to symmetric wedges only, this correction rule (equations (85), (86) of the text) is expected to possess a general validity, at least for symmetric bodies without too large curvatures, since the geometry of the body profile is only implicitly involved in the correction formula. This experimental study is perhaps one of a very few with the particular objective of scrutinizing various theoretical cavity-flow models.

Download Full-text