Getting the ducks in a row

Journal of Fluid Mechanics ◽

10.1017/jfm.2021.1020 ◽

2021 ◽

Vol 932 ◽

Author(s):

Simen Å. Ellingsen

Keyword(s):

Design Research ◽

Unmanned Vehicles ◽

Wave Resistance ◽

Resistance Force ◽

Total Drag ◽

Wave Interference ◽

Us Military ◽

Individual Wave ◽

Concomitant Resistance ◽

Shaped Pattern

Vessels – in the widest sense – travelling on a water surface continuously do work the water surrounding it, causing energy to be radiated in the form of surface waves. The concomitant resistance force, the wave resistance, can account for as much as half the total drag on the vessel, so reducing it to a minimum has been a major part of ship design research for many decades. Whether the ‘vessel’ is an ocean-going ship or a swimming duckling, the physics governing the V-shaped pattern of radiated waves behind it is in essence the same, and just as fuel economy is important for commercial vessels, it is reasonable to assume that also swimming waterfowl seek to minimise their energy expenditure. Using theory and methods from classic marine hydrodynamics, Yuan et al. (J. Fluid Mech., vol. 928, 2021, R2) consider whether, by organising themselves optimally, ducklings in a row behind a mother duck can reduce, eliminate or even reverse their individual wave resistance. They describe two mechanisms which they term ‘wave riding’ and ‘wave passing.’ The former is intuitive: the ducklings closest to the mother can receive a forward push by riding its mother's stern waves. The latter is perhaps a more striking phenomenon: when the interduckling distance is precisely right, every duckling in the row can, in principle, swim without wave resistance due to destructive wave interference. The phenomenon appears to be the same as motivates the recent US military research project Sea Train, a row of unmanned vehicles travelling in row formation.

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Experimentally-based investigation of effects of wave interference on the wave resistance of asymmetric di-hulls

Applied Ocean Research ◽

10.1016/j.apor.2017.03.018 ◽

2017 ◽

Vol 65 ◽

pp. 142-153 ◽

Cited By ~ 2

Author(s):

Dongchi Yu ◽

Pierre Lecointre ◽

Ronald W. Yeung

Keyword(s):

Wave Resistance ◽

Wave Interference

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Michell Investigation of the Significant Influence on the Hydrodynamic of a Warp-Chine Pentamaran

Journal of Ship Production and Design ◽

10.5957/jspd.02190011 ◽

2020 ◽

Vol 36 (03) ◽

pp. 202-212

Author(s):

W. Sulistyawati ◽

_ Yanuar ◽

A. S. Pamitran

Keyword(s):

Wave Pattern ◽

Wave Resistance ◽

Numerical Calculations ◽

Hydrodynamic Performance ◽

Hydrodynamic Characteristics ◽

Towing Tank ◽

Wave Interference ◽

Interference Wave ◽

Cfd Analyses ◽

Field Wave

This study attempted to investigate the hydrodynamic performance of various pentamaran configurations with a focus on the interference flow around the component hulls. A computer simulation was conducted based on Michell’s thin ship theory alongside a commercial CFD computation as a comparison. Experiments in the towing tank were performed to validate the numerical calculations, resulting in some hydrodynamic characteristics on the far-field wave pattern, wave interference, wave resistance, and total resistance. Analyses on both transversal and divergent waves were performed to assess the magnitude of wave resistance occurring due to the placement of the side hull to the main hull. Analyses on both waves were also conducted to assess the magnitude of wave resistance due to the placement of outriggers. Looking at the results, numerical calculations based on Michell’s theory were in parallel with experimental data, particularly at Fn greater than .4. Michell’s theory was observed as doing a little preferable agreement with the results of experiments than CFD. Besides, flow patterns obtained numerically from Michell’s and CFD analyses appeared as identical to photographs observed in a towing tank. This investigation identified that a configuration with aligning placement of the main to side hull on the formation of arrow tri-hull, near the Kelvin angle, would cancel the wave formed by the leading hull and can be used as a practical setting to reduce the total wave resistance.

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Application of brazing process design in optimization structure design of scraper

MATEC Web of Conferences ◽

10.1051/matecconf/201817503017 ◽

2018 ◽

Vol 175 ◽

pp. 03017

Author(s):

Bin Zhao ◽

Yuanbin Fang ◽

Linjie Zhang

Keyword(s):

Shear Strength ◽

Optimization Design ◽

Design Research ◽

Welding Process ◽

Rake Angle ◽

Structure Design ◽

Resistance Force ◽

Optimization Analysis ◽

Relief Angle ◽

Working Resistance

To effectively enhance the service life, the research of milling machine scraper structure design and welding process are optimized. Through the structural optimization analysis, the improved structure is obtained, and the working resistance force is reduced. The full factor test is used to optimize the brazing process, and the best parameters are obtained, which improves the shear strength. The accuracy of the model is verified by experiments. The results show that compared with the working resistance force, the improved scraper tends to be slow and the peak value is smaller. The cutting rake and relief angle of the scraper are optimized. When the cutting rake angle is 6° and the cutting relief angle is 9°, both working resistance force and impact force are minimum. It proves the accuracy of the simulation results. Using CT861 solder, brazing temperature is 75°C, and the brazing time is 10s. While the cooling method uses furnace cold, the minimum value of shear strength is 200MPa. The average working life of the scraper is raised from 800 hours to 1600 hours after the optimization design. Research results have guiding significance for the structure design and the welding process optimization of the scraper.

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Studies in wave resistance: the effect of parallel middle body

Proceedings of the Royal Society of London. Series A, Containing Papers of a Mathematical and Physical Character ◽

10.1098/rspa.1925.0059 ◽

1925 ◽

Vol 108 (745) ◽

pp. 77-92 ◽

Cited By ~ 3

Keyword(s):

Wave Length ◽

Wave Resistance ◽

Experimental Results ◽

Transverse Waves ◽

Wave Interference ◽

Length Increase ◽

Quarter Wave ◽

Varying Length ◽

The One ◽

Remarkable Agreement

1. If a ship is altered by inserting different lengths of parallel middle body between the same bow and stern, the main features of the variation in the wave resistance may be inferred from the principle of wave interference, and may be expressed in terms of a certain length, sometimes called the wave-making length of the ship. The problem proposed for examination is the alteration in this length with varying length of parallel middle body at the same speed, and, further, its variation for a given ship at different speeds. Recent discussions have attracted renewed attention to this problem. It may be said that there are two approximations based on experimental results of various kinds obtained from ship models. On the one hand the wave-making length is supposed to be approximately independent of speed for a given ship, and to increase directly with the increase of parallel middle body; on the other hand, an empirical formula which agrees with experimental results over a certain range makes the length increase with velocity, the increase being one-quarter of the increase in the wave-length of regular transverse waves. The following contribution to the solution of this problem is mathematical, and necessarily deals with a simplified form of ship. It is true that one cannot compare absolute values of the wave resistance with those of actual ship models; but it has been shown in former studies of the dependence of wave resistance on ship form that one obtains a rather remarkable agreement, at least in the character of the results and in the positions at which changes occur. Leaving detailed discussion of the present extension till later, it may be stated that as regards the two approximate formulæ mentioned above the results are intermediate; after an initial decrease the wave-making length increases until velocity, but not so rapidly as in the quarter wave-length formula.

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Reanalysis of the Sydney Harbor RiverCat Ferry

Journal of Marine Science and Engineering ◽

10.3390/jmse9020215 ◽

2021 ◽

Vol 9 (2) ◽

pp. 215

Author(s):

Lawrence J. Doctors

Keyword(s):

Detailed Analysis ◽

Good Accuracy ◽

Wave Generation ◽

Wave Resistance ◽

Affine Transformations ◽

Design And Development ◽

Total Drag ◽

Vessel Speed

In this paper, we revisit the hydrodynamics supporting the design and development of the RiverCat class of catamaran ferries operating in Sydney Harbor since 1991. More advanced software is used here. This software accounts for the hydrodynamics of the transom demisterns that experience partial or full ventilation, depending on the vessel speed. This ventilation gives rise to the hydrostatic drag, which adds to the total drag of the vessel. The presence of the transom also creates a hollow in the water. This hollow causes an effective hydrodynamic lengthening of the vessel, which leads to a reduction in the wave resistance. Hence, a detailed analysis is required in order to optimize the size of the transom. It is demonstrated that the drag of the vessel and the wave generation can be predicted with good accuracy. Finally, the software is also used to optimize the vessel further by means of affine transformations of the hull geometry.

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On The Wave Resistance of Surface Effect Ships

Journal of Ship Research ◽

10.5957/jsr.1971.15.1.22 ◽

1971 ◽

Vol 15 (01) ◽

pp. 22-32

Author(s):

Bohyun Yim

Keyword(s):

Froude Number ◽

Surface Effect ◽

Power Reduction ◽

Wave Resistance ◽

Low Speed ◽

Low Resistance ◽

Wave Interference ◽

Better Than

In an attempt to identify ways to reduce the peak wave resistance of surface effect ships, calculations of wave resistance are made for combinations of several singularity distributions with various parameters. Analyses are performed especially for the following components and parameters: various pressure planforms, the effect of sidewalls, the influence of sidewall camber, and the wave interference between the rectangular pressure planform with thin sidewalls and the front and rear skis. The result shows that, in general, the rectangular pressure planform is better than planforms of V-shaped bows and sterns. A gradual decrement of the sidewall displacement with the increasing Froude number is favorable, since not only the large buoyancy of sidewalls but also the low resistance helps the power reduction of SES for low-speed operations. Front and rear skis are helpful to reduce wave resistance for certain Froude numbers, although they may increase the drag for other Froude numbers. The camber of sidewall is not a good means for reducing the wave resistance of a rectangular pressure planform.

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