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Separation resistance

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Also known as: marine engineering

The drag due to separation of the boundary layer from a ship surface, and to eddying and backwash in the separation zone, is a form of pressure resistance. This means that, like wave-making resistance and some types of roughness resistance, it is due to forces exerted at right angles to the hull surface. Like these resistances, it varies as a power of the ship speed.

Hydrodynamic knowledge of separation phenomena and the physical laws which govern them has not progressed to the point where the onset of separation can be predicted in advance with certainty and where the magnitude of separation resistance can be calculated. It is known, however, that the pressure in such a zone is less than atmospheric, so that the water literally sucks backward on the ship. If air can be led to the zone to displace the eddying water, the suction is removed. When a motorboat with a square or transom stern extending below the water is speeded up until the stern “clears,” the backwash and eddying disappear. With the square stern exposed to the atmosphere, the separation resistance also disappears.

Resistance of submarines

When a submarine submerges to a depth below the surface equal to four or more times its maximum diameter or its hull depth, the surface disturbance resulting from its forward motion becomes negligible and its wave-making resistance practically disappears. This is a great advantage, especially at high speed, despite the increase in wetted surface and friction resistance caused by taking the whole craft under the water. However, old-style submersible craft have considerable amounts of gear above the water line, such as flat decks, rails, anchors, capstans, chocks, and similar fittings, put there for operation on the surface. It is difficult to streamline them for low resistance under water. Modern true submarines, intended to spend almost all of their operational time fully submerged under nuclear power, have dispensed with most of these irregularities. Furthermore, their length-to-diameter ratios have been reduced so that frictional resistance at high speeds is minimized.

Resistance in shallow and restricted waters

The forces on a ship traversing shallow waters are governed by the presence of solitary waves caused by ship motion and other disturbances. If the ship speed is slightly less than the solitary wave speed, the ship runs uphill on the back of this wave so that its hydrodynamic resistance is increased by the slope drag. If it can be speeded up so as to run slightly faster than the wave, it slides downhill on the face of the wave and its resistance is reduced below that of its deepwater resistance. The speed of progressive waves of a given length is less in shallow than in deep water. If a tug, for example, is running at a speed in shallow water at which it has a crest at the bow and another at the stern, its speed must be decreased if the two crests are to be kept at the advantageous positions indicated. At the same time, the crests may be higher and the trough may be lower because waves become steeper as they enter shallow water. A fast craft also squats more deeply at the stern when running in shallow water. In fact, this increase in squat may be sufficient to cause the craft to scrape bottom even though it has plenty of water under it when at rest.

When the clearance between the bottom of the ship and the bed of the water body is initially small, the water that flows under the ship is speeded up, with an increase in friction resistance on the ship. When the sides or walls of the channel are close to the ship, the lateral constriction speeds up this flow still further. Methods of approximating the increased resistance and the depth of water necessary to give the equivalent of deepwater resistance are available.

Self-propelled craft designed for efficient operation in shallow and restricted waters must have: (1) provision for adequate flow of water to the propellers; (2) adequate shielding to prevent drawing air from the surface; and (3) rudders of extra-large area, usually one rudder behind each propeller, to overcome the horizontal forces resulting from the closeness of adjacent banks or of other craft being met in a channel.

Ship form for minimum resistance

Certain general rules for ship form based upon hydrodynamics are available: (1) The use of easy and fair surfaces along the general paths followed by the water flow. Small changes of curvature in the flow lines are particularly important. (2) At and near the surface the flow lines must follow the surface or the wave profile. Since most of the wave-making resistance is generated by pressure disturbances near the surface, easy curvature is important there. Proof of good design in this respect is low wave crests and shallow troughs around the ship when running. (3) Most of the flow in almost any type of ship goes under the bottom rather than around the sides, hence the ship form must not interfere with it. (4) Submerged bulbs intended to produce surface-wave systems that will partly neutralize the crests and troughs produced by pressure disturbances elsewhere require careful design and positioning. (5) Probably the most important feature in shaping the hull of a self-propelled craft is to provide a good flow of water to the propulsion devices. So far as known, this calls for the highest practicable degree of uniformity of relative velocity over the whole thrust-producing area, the greatest possible degree of flow opposite to the direction of advance of the blades of the propulsion device, and the greatest mass density of the water in which the device is to work. Concerning the last item, it is known that the water entering the propeller disks of destroyers and other high-speed craft contains many air and gas bubbles. In the aggregate, the reduction of mass density due to them can be appreciable.

It is important to note, however, that the optimum ship design for a given mission may not be the one that has the form of minimum resistance. In the overall economic picture, gains from better stowage of cargo, for example, may outweigh a modest increase in fuel consumption. Developable hull forms have been designed for small craft that are cheaper to build and offer little, if any, resistance penalty.