Stuart D. Jessup scite author profile

Stuart D. Jessup

5Publications

62Citation Statements Received

3Citation Statements Given

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Naval Surface Warfare Center

Publications

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Tip-Vortex Induced Cavitation on a Ducted Propulsor

Chesnakas

Jessup

2003

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An extensive experimental investigation was carried out to examine tip-vortex induced cavitation on a ducted propulsor. The flowfield about a 3-bladed, ducted rotor operating in uniform inflow was measured in detail with three-dimensional LDV; cavitation inception was measured; and a correlated hydrophone/high-speed video system was used to identify and characterize the early, sub-visual cavitation events. Two geometrically-similar, ducted rotors were tested over a Reynolds number range from 1.4×106 to 9×106 in order to determine how the tip-vortex cavitation scales with Reynolds number. Analysis of the data shows that exponent for scaling tip-vortex cavitation with Reynolds number is smaller than for open rotors. It is shown that the parameters which are commonly accepted to control tip-vortex cavitation, vortex circulation and vortex core size, do not directly control cavitation inception on this ducted rotor. Rather it appears that cavitation is initiated by the stretching and deformation of secondary vortical structures resulting from the merger of the leakage and tip vortices.

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Measurement of the pressure distribution on two model propellers / by Stuart D. Jessup.

Jessup¹

1982

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Measurement of Steady and Unsteady Duct Loads for Propeller 4381 at Crashback Conditions in the 36 in. Water Tunnel

Donnelly¹,

Jessup²,

Etebari³

2010

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Public reporting burden for this collection of information Is estimated to average 1 hour per response, including the time for reviewing Instructions, searching existing data sources, gathering and maintaining the data needed, and completing and reviewing the collection of information Send comments regarding this burden estimate or any other aspect of this collection of information, including suggestions for reducing this burden to Washington Headquarters Services, Directorate for information. Operations and Reports,

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Cavitation and 3-D LDV Tip-Flowfield Measurements of Propeller 5168

Chesnakas¹,

Jessup²

1998

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Directorate Report, CRDKNSWC/HD-1460-02, "Cavitation and 3-D LDV Tip-Flowfield Measurements of Propeller 5168 by Christopher J. Chesnakas and Stuart Jessup (May 1998) (2) Customer Project Survey Form 5200-20A (Rev 4) 1. Enclosure (1) is forwarded for your information and retention. 2. It is requested that enclosure (2) be completed and returned to the Carderock Division, Naval Surface Warfare Center. Customer project surveys are conducted at the completion of a project. They are used at the Department level to control and verify the system process capability. The forms will be reviewed for customer comments, including complaints and recommendations. Corrective actions will be taken.

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Tip Vortex Cavitation Inception Scaling for High Reynolds Number Applications

Shen

Gowing

Jessup

2009

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Tip vortices generated by marine lifting surfaces such as propeller blades, ship rudders, hydrofoil wings, and antiroll fins can lead to cavitation. Prediction of the onset of this cavitation depends on model tests at Reynolds numbers much lower than those for the corresponding full-scale flows. The effect of Reynolds number variations on the scaling of tip vortex cavitation inception is investigated using a theoretical flow similarity approach. The ratio of the circulations in the full-scale and model-scale trailing vortices is obtained by assuming that the spanwise distributions of the section lift coefficients are the same between the model-scale and the full-scale. The vortex pressure distributions and core sizes are derived using the Rankine vortex model and McCormick’s assumption about the dependence of the vortex core size on the boundary layer thickness at the tip region. Using a logarithmic law to describe the velocity profile in the boundary layer over a large range of Reynolds number, the boundary layer thickness becomes dependent on the Reynolds number to a varying power. In deriving the scaling of the cavitation inception index as the ratio of Reynolds numbers to an exponent m, the values of m are not constant and are dependent on the values of the model- and full-scale Reynolds numbers themselves. This contrasts traditional scaling for which m is treated as a fixed value that is independent of Reynolds numbers. At very high Reynolds numbers, the present theory predicts the value of m to approach zero, consistent with the trend of these flows to become inviscid. Comparison of the present theory with available experimental data shows promising results, especially with recent results from high Reynolds number tests. Numerical examples of the values of m are given for different model- to full-scale sizes and Reynolds numbers.

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Stuart D. Jessup

Tip-Vortex Induced Cavitation on a Ducted Propulsor

Measurement of the pressure distribution on two model propellers / by Stuart D. Jessup.

Measurement of Steady and Unsteady Duct Loads for Propeller 4381 at Crashback Conditions in the 36 in. Water Tunnel

Cavitation and 3-D LDV Tip-Flowfield Measurements of Propeller 5168

Tip Vortex Cavitation Inception Scaling for High Reynolds Number Applications

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