Experimental Investigation of Mooring Line Loading Using Large and Small-Scale Models

Kitney, Neil; Brown, David T.

doi:10.1115/1.1342159

Cited by 16 publications

(6 citation statements)

References 5 publications

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“…Vibrations of one-dimensional systems (i.e., systems with cross-sectional dimension much smaller than their length) suspended under the influence of a downward force have long been of interest in the context of such applications as beams, cables supporting suspension bridges, and ship moorings. − Such systems display a wide range of behavior, depending on the amount of slack present in the system, the downward force, and the aspect ratio. Previous studies, which have largely been analytical, have been restricted to certain limiting cases of these parameters.…”

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confidence: 99%

Modeling a Suspended Nanotube Oscillator

2005

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We present a general study of oscillations in suspended one-dimensional elastic systems clamped at each end, exploring a wide range of slack (excess length) and downward external forces. Our results apply directly to recent experiments in nanotube and silicon nanowire oscillators. We find the behavior to simplify in three well-defined regimes which we present in a dimensionless phase diagram. The frequencies of vibration of such systems are found to be extremely sensitive to slack.Vibrations of one-dimensional systems (i.e. systems with cross-sectional dimension much smaller than their length) suspended under the influence of a downward force have long been of interest in the context of such applications as beams, cables supporting suspension bridges and ship moorings [1,2,3]. Such systems display a wide range of behavior, depending on the amount of slack present in the system, the downward force, and the aspect ratio. Previous studies, which have largely been analytical, have been restricted to certain limiting cases of these parameters. Recently work on oscillating nanoscale systems, such as carbon nanotubes [4] and silicon nanowires [5], has opened the possibility of experimentally exploring such vibrations in entirely new regimes. In the present work, we study numerically the oscillations of a one dimensional elastic system over an extensive range of both the slack and force parameters, providing insight into the physics which separates this parameter space into three distinct regimes of behavior.The treatment below is entirely general with illustrative examples taken from parameters relevant to carbon nanotubes. Since their discovery in 1991 [6], nanotubes have found many applications in device technology due to their small size, robust structure and superior elastic properties [7,8,9,10]. Many of these applications involve the use of nanotubes as mechanical oscillators, making theoretical understanding of the vibrational properties of nanotubes in various geometries of current interest [4,11]. Recent experiments [12] have studied the behavior of the transverse vibrations of a suspended nanotube clamped at both ends, under the action of a downward force, as sketched in Figure 1. These suspended nanotubes generally have around 1% slack, denoted in this work by s, which we define to be the ratio of the excess length of the tube to the distance between clamping points.Analytic model and computational techniques -The potential energy of a one-dimensional elastic continuum under a uniform downward force isHere, l represents distance along the system of unstretched length L; u(l), R(l) and z(l) represent the local strain, radius of curvature and vertical displacement, 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000111 111 respectively; E and F are the extensional and flexural rigidities; and f is the downward force per unit length. For single-walled nanotubes with diamet...

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confidence: 99%

Modeling a Suspended Nanotube Oscillator

2005

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“…Thomas and Hearn [ 22 ] indicated that the out-of-plane seabed friction can be negligible and that in-plane effects can influence the peak dynamic tension. Kitney and Brown [ 23 ] presented two different scale experiments to validate the results of other scholars. Qiao and Ou [ 24 ] calculated the hydrodynamic drag damping of single-component mooring line and obtained linearized damping coefficients.…”

Section: Introductionmentioning

confidence: 87%

Mooring Line Damping Estimation for a Floating Wind Turbine

Qiao

2014

The Scientific World Journal

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The dynamic responses of mooring line serve important functions in the station keeping of a floating wind turbine (FWT). Mooring line damping significantly influences the global motions of a FWT. This study investigates the estimation of mooring line damping on the basis of the National Renewable Energy Laboratory 5 MW offshore wind turbine model that is mounted on the ITI Energy barge. A numerical estimation method is derived from the energy absorption of a mooring line resulting from FWT motion. The method is validated by performing a 1/80 scale model test. Different parameter changes are analyzed for mooring line damping induced by horizontal and vertical motions. These parameters include excitation amplitude, excitation period, and drag coefficient. Results suggest that mooring line damping must be carefully considered in the FWT design.

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“…The exhaustion of these fields and the continuous demand for hydrocarbon products has attracted offshore industry experts to explore and produce from fields located in deeper waters. These floating drilling/production systems are moored or tethered to the seabed via TCs [1]. For stationkeeping seabed operating vehicles, continuous human presence in the loop necessitates the utilization of TCs.…”

Section: Introductionmentioning

confidence: 99%

“…TC analysis is a challenging task due to the difficulty in modeling the hydrodynamic forces, which in turn depend on the prevailing physical conditions. Hence, there is a need for a reliable and efficient solution technique for determining the cable profile and tensions [1,[9][10][11].…”

Section: Introductionmentioning

confidence: 99%

Analytical and Numerical Study of Underwater Tether Cable Dynamics for Seabed Walking Robots Using Quasi-Static Approximation

Khan,

Wang,

et al. 2023

JMSE

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In this study, the dynamics of tether cables (TCs) that connect a surface ship and a walking robotic vehicle on the seabed are numerically investigated. The main aim of this study is to develop a reliable prediction model for the dynamic behavior of TCs attached to a seabed walking robot. This system consists of a surface ship, underwater manned seabed walking robot (UMSWR), TC, and winch. The study is comprised of mathematical modeling and numerical simulations of the developed governing equations for the TC dynamics. A relatively simple and efficient mathematical analysis method is proposed to determine the configuration and forces on the TC under a steady state. The problem is solved using the quasi-static technique and lumped mass parameters for discretizing and modeling the dynamics of the TC. Based on the static analysis of the Morrison equation and finite segment method, analytical formulas of the steady-state equation of TC were obtained and solved. The effects of variable water density and variable underwater currents are included in the cable behavior. Consequently, the two-dimensional TC profile and axial tension were estimated in a steady-state configuration. The developed equations were simulated in MATLAB software. Several numerical simulation examples were worked out, demonstrating the accurate performance of the method. Various input parameters of the system and their relationships with the output values were investigated, thereby demonstrating the versatility of the method.

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Experimental Investigation of Mooring Line Loading Using Large and Small-Scale Models

Cited by 16 publications

References 5 publications

Modeling a Suspended Nanotube Oscillator

Modeling a Suspended Nanotube Oscillator

Mooring Line Damping Estimation for a Floating Wind Turbine

Analytical and Numerical Study of Underwater Tether Cable Dynamics for Seabed Walking Robots Using Quasi-Static Approximation

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