Investigation of added mass and damping coefficients of underwater rotating propeller using a frequency-domain panel method

This paper presents the calculation of the hydrodynamic forces exerted on an oscillating circular cylinder when it moves perpendicular to its axis in infinitely deep water covered by compressed ice. The cylinder can oscillate both horizontally and vertically in the course of its translational motion. In the linear approximation, a solution is found for the steady wave motion generated by the cylinder within the hydrodynamic set of equations for the incompressible ideal fluid. It is shown that, depending on the rate of ice compression, both normal and anomalous dispersion can occur in the system. In the latter case, the group velocity can be opposite to the phase velocity in a certain range of wavenumbers. The dependences of the hydrodynamic loads exerted on the cylinder (the added mass, damping coefficients, wave resistance and lift force) on the translational velocity and frequency of oscillation were studied. It was shown that there is a possibility of the appearance of negative values for the damping coefficients at the relatively big cylinder velocity; then, the wave resistance decreases with the increase in cylinder velocity. The theoretical results were underpinned by the numerical calculations for the real parameters of ice and cylinder motion.

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Measured Static and Rotordynamic Coefficient Results for a Rocker-Pivot, Tilting-Pad Bearing With 50 and 60% Offsets

Journal of Engineering for Gas Turbines and Power ◽

10.1115/1.4004723 ◽

2012 ◽

Vol 134 (5) ◽

Cited By ~ 12

Author(s):

Chris D. Kulhanek ◽

Dara W. Childs

Keyword(s):

Dynamic Stiffness ◽

Mass Matrix ◽

Excitation Frequency ◽

Quadratic Function ◽

Added Mass ◽

Damping Coefficients ◽

Stiffness Coefficients ◽

Tilting Pad ◽

Frequency Independent ◽

Direct Stiffness

Static and rotordynamic coefficients are measured for a rocker-pivot, tilting-pad journal bearing (TPJB) with 50 and 60% offset pads in a load-between-pad (LBP) configuration. The bearing uses leading-edge-groove direct lubrication and has the following characteristics: 5-pads, 101.6 mm (4.0 in) nominal diameter,0.0814 -0.0837 mm (0.0032–0.0033 in) radial bearing clearance, 0.25 to 0.27 preload, and 60.325 mm (2.375 in) axial pad length. Tests were performed on a floating bearing test rig with unit loads from 0 to 3101 kPa (450 psi) and speeds from 7 to 16 krpm. Dynamic tests were conducted over a range of frequencies (20 to 320 Hz) to obtain complex dynamic stiffness coefficients as functions of excitation frequency. For most test conditions, the real dynamic stiffness functions were well fitted with a quadratic function with respect to frequency. This curve fit allowed for the stiffness frequency dependency to be captured by including an added mass matrix [M] to a conventional [K][C] model, yielding a frequency independent [K][C][M] model. The imaginary dynamic stiffness coefficients increased linearly with frequency, producing frequency-independent direct damping coefficients. Direct stiffness coefficients were larger for the 60% offset bearing at light unit loads. At high loads, the 50% offset configuration had a larger stiffness in the loaded direction, while the unloaded direct stiffness was approximately the same for both pivot offsets. Cross-coupled stiffness coefficients were positive and significantly smaller than direct stiffness coefficients. Negative direct added-mass coefficients were obtained for both offsets, especially in the unloaded direction. Cross-coupled added-mass coefficients are generally positive and of the same sign. Direct damping coefficients were mostly independent of load and speed, showing no appreciable difference between pivot offsets. Cross-coupled damping coefficients had the same sign and were much smaller than direct coefficients. Measured static eccentricities suggested cross coupling stiffness exists for both pivot offsets, agreeing with dynamic measurements. Static stiffness measurements showed good agreement with the loaded, direct dynamic stiffness coefficients.

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A review of the researches on the added mass and damping coefficients for the heave plates of the offshore platforms at translational and rotational oscillations

مهندسی دریا ◽

10.29252/marineeng.16.31.65 ◽

2020 ◽

Vol 16 (31) ◽

pp. 65-81

Author(s):

Abuzar Abazari ◽

Mehdi Behzad ◽

◽

Keyword(s):

Added Mass ◽

Offshore Platforms ◽

Damping Coefficients ◽

Rotational Oscillations

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On the Radiation and Diffraction of Surface Waves by Submerged Spheroids

Journal of Ship Research ◽

10.5957/jsr.1989.33.2.84 ◽

1989 ◽

Vol 33 (02) ◽

pp. 84-92

Author(s):

G. X. Wu ◽

R. Eatock Taylor

Keyword(s):

Degrees Of Freedom ◽

Velocity Potential ◽

Three Dimensional ◽

Added Mass ◽

Wave Radiation ◽

Legendre Functions ◽

Incoming Wave ◽

Six Degrees Of Freedom ◽

Damping Coefficients ◽

Exciting Forces

The problem of wave radiation and diffraction by submerged spheroids is analyzed using linearized three-dimensional potential-flow theory. The solution is obtained by expanding the velocity potential into a series of Legendre functions in a spheroidal coordinate system. Tabulated and graphical results are provided for added mass and damping coefficients of various spheroids undergoing motions in six degrees of freedom. Graphs are also provided for exciting forces and moments corresponding to a range of incoming wave angles.

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Ship Motions in Shallow Water

Journal of Ship Research ◽

10.5957/jsr.1970.14.4.317 ◽

1970 ◽

Vol 14 (04) ◽

pp. 317-328 ◽

Cited By ~ 1

Author(s):

E. O. Tuck

Keyword(s):

Shallow Water ◽

Water Depth ◽

Incident Wave ◽

Degrees Of Freedom ◽

Added Mass ◽

Exciting Force ◽

Ship Motions ◽

Wave System ◽

Six Degrees Of Freedom ◽

Damping Coefficients

The problem discussed concerns small motions of a ship, in all six degrees of freedom, but at zero speed of advance, due to an incident wave system in shallow water of depth comparable with the ship's draft. The problem is completely formulated for an arbitrary ship, and is partially solved for the case when the ship is slender and the wavelength much greater than the water depth. Sample numerical computations of heave, pitch, and sway added mass and damping coefficients and the sway exciting force are presented.

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An Analysis of Heave Added Mass and Damping of a Surface-Effect Ship

Journal of Ship Research ◽

10.5957/jsr.1981.25.1.44 ◽

1981 ◽

Vol 25 (01) ◽

pp. 44-61

Author(s):

C. H. Kim ◽

S. Tsakonas

Keyword(s):

Free Surface ◽

High Speed ◽

Surface Effect ◽

Practical Method ◽

Added Mass ◽

Damping Coefficients ◽

Calm Water ◽

Surface Effect Ship ◽

Long Time ◽

Computational Procedures

The analysis presents a practical method for evaluating the added-mass and damping coefficients of a heaving surface-effect ship in uniform translation. The theoretical added-mass and damping coefficients and the heave response show fair agreement with the corresponding experimental values. Comparisons of the coupled aero-hydrodynamic and uncoupled analytical results with the experimental data prove that the uncoupled theory, dominant for a long time, that neglects the free-surface effects is an oversimplified procedure. The analysis also provides means of estimating the wave elevation of the free surface, the escape area at the stern and the volume which are induced by a heaving surface-effect ship in uniform translation in otherwise calm water. Computational procedures have been programmed in the FORTRAN IV language and adapted to the PDP-10 high-speed digital computer.

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Effects of Fluid Motions in Liquid Tanks on Vessel Motions Using a Simple Panel Method

Volume 4: Ocean Engineering; Ocean Renewable Energy; Ocean Space Utilization, Parts A and B ◽

10.1115/omae2009-80071 ◽

2009 ◽

Cited By ~ 1

Author(s):

Yusong Cao ◽

Fuwei Zhang

Keyword(s):

Natural Frequencies ◽

Added Mass ◽

Panel Method ◽

Stiffness Matrices

This paper presents a simple and fast panel method to include the effect of liquid tanks of a vessel in the prediction of the natural frequencies of the vessel motions. The effects are expressed in terms of modifications to the added mass and stiffness matrices of the vessels with the liquids in the tanks assumed being rigid. An application example for a vessel with two internal liquid tanks is demonstrated.

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Surge motion on a floating cylinder in water of finite depth

International Journal of Mathematics and Mathematical Sciences ◽

10.1155/s0161171203209285 ◽

2003 ◽

Vol 2003 (57) ◽

pp. 3643-3656 ◽

Cited By ~ 1

Author(s):

Dambaru D. Bhatta

Keyword(s):

Velocity Potential ◽

Separation Of Variables ◽

Finite Depth ◽

Added Mass ◽

Computational Results ◽

Complex Matrix ◽

Interior Region ◽

Exterior Region ◽

Damping Coefficients ◽

Calm Water

We derived added mass and damping coefficients of a vertical floating circular cylinder due to surge motion in calm water of finite depth. This is done by deriving the velocity potential for the cylinder by considering two regions, namely, interior region and exterior region. The velocity potentials for these two regions are obtained by the method of separation of variables. The continuity of the solutions has been maintained at the imaginary interface of these regions by matching the functions and gradients of each solution. The complex matrix equation is numerically solved to determine the unknown coefficients. Some computational results are presented for different depth-to-radius and draft-to-radius ratios.

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Added mass coefficients for submerged bodies by a low-order panel method

10.2514/6.1993-788 ◽

1993 ◽

Author(s):

ISKENDER SAHIN ◽

JAN CRANE ◽

KENNARD WATSON

Keyword(s):

Added Mass ◽

Panel Method ◽

Low Order

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Added Mass and Damping for Cylinder Vibrations Within a Confined Fluid Using Deforming Finite Elements

Journal of Fluids Engineering ◽

10.1115/1.3242662 ◽

1987 ◽

Vol 109 (3) ◽

pp. 283-288 ◽

Cited By ~ 4

Author(s):

R. Chilukuri

Keyword(s):

Finite Elements ◽

Vibration Amplitude ◽

Stokes Equations ◽

Outer Cylinder ◽

Added Mass ◽

Navier Stokes ◽

Element Analysis ◽

Damping Coefficients ◽

Moving Cylinder ◽

Fluid Damping

Added mass and fluid damping coefficients for vibrations of an inner cylinder that is enclosed by a concentric outer cylinder are determined by finite element analysis of the unsteady, laminar, incompressible flow in the annulus. Continuously deforming space-time finite elements are used to track the moving cylinder and the changing shape of the space domain. For small cylinder vibration amplitudes, the present results agree well with the work of earlier investigators who solved the linearized Navier-Stokes equations on a fixed mesh. Fluid damping coefficients are shown to increase with vibration amplitude. Added mass coefficients may either increase or decrease with increasing vibration amplitude.

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