KR20020077112A - Method and device for diminish in drag by turbulent flow control of hull surface of ship - Google Patents

Abstract

PURPOSE: A method and a device for reducing the drag by controlling the turbulence of the surface of a body are provided to reduce the ocean current resistance applied to the running of a ship by reducing the drag due to the turbulence of the surface of the ship body. CONSTITUTION: A device for reducing the drag includes a pipe housing(110) installed on a body surface of a ship(100) and having many slits(111), an air pipe installed in the pipe housing and contracting and expanding by the air pumped, and a pump installed in the ship body to contract and expand the air pipe and to supply air to the air pipe. A fluid is sucked and jetted through the slits by expanding and contracting the air pipe. Thus, the flow fields of the turbulence formed on the surface of the ship body is changed. Thereby, the frictional resistance is reduced.

Description

Method and device for drag reduction by turbulence control of ship surface {Method and device for diminish in drag by turbulent flow control of hull surface of ship}

The present invention relates to a method and apparatus for reducing drag by controlling turbulence of a ship's hull, and more particularly, to reduce turbulence and reduce fuel resistance by controlling turbulence by repeatedly inhaling and ejecting fluid flowing along a ship's hull surface. The present invention relates to a method and a device for reducing drag by turbulence control of a ship's hull surface to reduce the pressure.

As the ship sails, the frictional resistance of the hull surface caused by the vortex on the hull surface is so large that it occupies 80% or more of the total resistance in the case of large tankers.

In order to reduce the frictional resistance of the hull surface, active researches have recently been conducted. However, a method of ejecting air from the bow side or a method of ejecting syrup has been studied, but it is difficult to obtain a frictional resistance reduction effect. Suffer.

The present invention has been proposed to solve the above problems, the purpose of which is to suck and eject the fluid flowing along the hull surface of the ship, and to control the turbulence of the hull surface by adjusting the injection angle formed with the hull surface The present invention provides a method for reducing drag by turbulence control of a ship's hull surface.

Another object is to install a flexible air pipe or valve housing along the hull surface of the ship to control the turbulent boundary layer at the hull surface by repeatedly operating the intake and ejection of fluid flowing along the surface from the inside of the hull. The present invention provides a drag reduction device based on turbulence control of a ship's hull surface.

Still another object is to install a device using the flexible air pipe or valve to control the turbulence locally by installing the bow or stern of the vessel.

1 is a view showing an experimental apparatus for local suction and injection.

2 is a distribution chart showing wall friction coefficients under various suction conditions at an excitation frequency.

3 is a distribution chart showing wall friction coefficients under various injection conditions at an excitation frequency.

4 is a distribution diagram showing the wall friction coefficient according to the spray angle.

5 is a schematic installation diagram for explaining a drag reduction device by the turbulent surface turbulence control of the ship according to the present invention.

Figure 6 is a cross-sectional view showing a pipe housing of the drag reduction device by the ship's hull surface turbulence control according to the present invention.

Figure 7 is a front sectional view for explaining the connection state of the pump of the drag reduction device by the turbulent surface turbulence control of the ship according to the present invention.

8 is a detailed side view for explaining a drag reduction device by the turbulent surface turbulence control of a ship according to another invention.

9 is a cross-sectional view showing the pipe housing of the drag reduction device by the turbulent surface turbulence control of the ship according to another invention.

10 is a front sectional view for explaining a connection state of the motor of the drag reduction device by the turbulent surface turbulence control of the ship according to another invention.

11 is a cross-sectional view showing a state in which a pipe housing of a drag reduction device by turbulence control of a ship's hull surface according to another invention is installed inside the hull.

※ Explanation of codes for main parts of drawing

100: vessel 101: hull surface

102: bow part 103: stern part

110, 210: pipe housing 111, 211: slit

120: flexible air line 130: pump

220: valve 220a: top valve

220b: lower valve 230: first rod

240: second load 250: motor

In order to achieve the above object, the drag reduction method according to the ship's hull surface turbulence control allows the fluid flowing along the ship's hull surface to be sucked and ejected throughout the hull to change the turbulent flow field, and It is to reduce the frictional resistance by adjusting the injection angle to be made.

The apparatus for achieving a drag reduction by the hull surface turbulence control of the ship of the present invention includes a pipe housing having a plurality of slits installed on the hull surface of the ship; A flexible air pipe installed inside the pipe housing to perform contraction and expansion; It is preferred that the device be configured as a device comprising a pump connected to said flexible air line to allow suction and compression of air.

The apparatus for achieving a drag reduction by the turbulent surface turbulence control of the ship of the present invention is installed on the ship's hull surface, the pipe housing formed a plurality of slits; A valve installed inside the pipe housing and positioned above and below the slit; A first rod connecting the upper valves positioned above the slit; A second rod connecting lower valves positioned below the slit; It is preferable that the motor is installed inside the vessel and includes a motor connected to the first and second rods to drive the first and second rods.

In order to implement the present invention as described above, the flow field change of the turbulent boundary layer due to local disturbance was analyzed by numerical analysis.

1 is a view showing an experimental apparatus for local suction and injection, Figure 2 is a distribution diagram showing the wall friction coefficient under various suction conditions at the excitation frequency, Figure 3 is a distribution diagram showing the wall friction coefficient under various injection conditions at the excitation frequency 4 is a distribution diagram showing the wall friction coefficient according to the spray angle.

As shown in FIG. 1, the apparatus for experiment includes a flat plate 10 having a slot 11 to replace the hull surface, and install a trip line 20 at one end of the upper surface of the flat plate 10. A rough surface 30 is installed next to the trip line 20, and a speaker 40 for local suction and local injection is installed under the slot 11 of the flat plate 10.

Then, the turbulent boundary layer due to flow is formed above the flat plate 10 on which the trip line 20 is installed to perform local suction and local injection by the speaker 40 through the slot 11 of the flat plate 10. do.

In the course of the local suction and local injection, the injection is well done, but the suction is not made better than expected due to the compression effect of the air. Therefore, numerical analysis was performed according to the degree of suction. As shown in FIG. 2, in the area near the slot, a strong flow of the flow energy descends to the vicinity of the wall with the increase of the suction amount, thereby increasing the wall friction coefficient. It can be seen that if the suction amount is increased, the average friction coefficient decreases again because the fluidized bed mixed with the injection causes reverse flow in the vicinity of the slot. Also, downstream from the slot, the wall friction coefficient decreases with the increase of the suction amount.

Meanwhile, as shown in FIG. 3, the wall friction coefficient according to the change in the injection amount is not affected by the increase in the injection amount downstream of the slot, while decreasing near the slot as the injection amount increases. Shows. This phenomenon is caused by the strong reverse direction near the slot at the time of injection, and the stronger the injection, the stronger the reverse flow and the average friction coefficient gradually decreases.

In addition, the correlation between the spray angle and the wall friction coefficient for local disturbance shows a friction coefficient reduction effect in a region where spraying at an angle of 60 ° is more frequent than spraying perpendicular to the wall as shown in FIG. 4. It can be seen. If the injection angle is 90 ° or more, the convective velocity generated in the slot is reduced so that it does not reach downstream. As the injection angle is increased, the area that gradually decreases the friction coefficient decreases, and when the injection angle is 60 ° or less, It is shown that the friction coefficient reduction area is rather reduced because the generation of the recycle area generated during the injection is suppressed.

Preferred embodiments of the present invention based on the analysis results according to the numerical analysis as described above in detail with reference to the drawings.

5 is a schematic installation diagram for explaining a drag reduction device by the ship's hull surface turbulence control according to the present invention, Figure 6 is a drag reduction device by the ship's hull surface turbulence control according to the present invention Fig. 7 is a cross sectional view showing a pipe housing, and Fig. 7 is a front sectional view for explaining a connection state of a pump of a drag reduction device by turbulence control of a ship surface according to the present invention, and Fig. 8 is a ship surface of a ship according to another invention. 9 is a cross-sectional view illustrating a pipe housing of a drag reduction device by turbulence control of a ship's hull surface according to another invention, and FIG. 10 is a cross-sectional view illustrating a drag reduction device by turbulent control. Fig. 11 is a front sectional view for explaining the connection state of the motor of the drag reduction device by the turbulent surface turbulence control of the ship according to another invention This is a cross-sectional view showing that the pipe housing of the drag reduction device by the turbulent surface turbulence control of the ship is installed inside the hull.

The drag reduction apparatus according to the turbulent surface turbulence control of the present invention according to the drawings is divided into a case using a flexible air pipe inside the pipe housing and a case using the valve inside the pipe housing by mechanical driving.

In the case of using the flexible air pipe, as shown in FIGS. 5 to 7, a pipe housing 110 in which a plurality of slits 111 are formed along the hull surface 101 of the vessel 100 is vertically installed in a belt shape. do. At this time, the pipe housing 110 is a hollow body (mid-body) is preferably a streamline, but can be expressed in a variety of shapes, such as a semi-circle or elliptical, the slit 111 may be a circular hole, depending on the type and speed of the vessel Therefore, it is preferable that the injection angle with the hull surface 101 is positioned so as to form an angle of 60 degrees.

The flexible air pipe 120 is installed inside the pipe housing 110 in which the slit 111 is formed, and a pump 130 for sucking and compressing air for contracting and expanding the flexible air pipe 120 is connected. To be. At this time, the pump 130 connected to the flexible air pipe 120 is installed in the vessel 100.

Meanwhile, in the case of using the valve, as shown in FIGS. 8 to 10, a pipe housing 210 having a plurality of slits 211 formed along the hull surface 101 of the vessel 100 is vertically installed in a belt shape. do. Here, the pipe housing 210 is preferably a hollow body, but a streamline type is preferable, but can be expressed in various shapes such as a semi-circle or an ellipse, and the slit 211 may be a circular hole, and the type and speed of the vessel may be different. Therefore, it is preferable that the injection angle with the hull surface 101 is positioned so as to form an angle of 60 degrees.

The valve 220 is installed inside the pipe housing 210, but the upper valve 220a and the lower valve 220b are positioned above and below the slit 211.

The first rod 230 is connected to the valve 220 installed in the pipe 210, but only the upper valves 220a positioned at the upper portion of the slit 211 are connected to each other, and the second valve is connected to the valve 220. The rod 240 is connected but only the lower valves 220b positioned below the slit 211 are connected.

The first and second rods 230 and 240 are connected to the motor 250 in a predetermined structure to drive them, and the valves 220a are caused by the first and second rods 230 and 240 descending by the driving of the motor 250. Seawater is pushed out or sucked through the slits 211 as 220b faces each other and contracts or expands. At this time, the motor 250 is installed inside the ship.

Meanwhile, the drag reduction device of the ship using the flexible air pipe 120 or the valve 220 may be locally installed on the bow portion 102 and the stern portion 103 of the ship.

Referring to the action of the drag reduction device of the ship by turbulence control of the hull surface according to the present invention having such a configuration as follows.

First, in the case of using the flexible air pipe 120 when driving the pump 130 installed in the interior of the vessel 100 when the flexible air pipe 120 installed inside the pipe housing 110 is compressed in the pipe housing When the air is expanded, and the air in the air pipe 120 is exhausted, it contracts to repeat the operation of ejecting or injecting the fluid into the housing through the slit 111.

That is, as the flexible air tube 120 expands and contracts as the air is compressed and exhausted in the flexible air tube 120, the flexible air tube 120 contracts and the empty space inside the pipe housing 110. As a result, the fluid around the hull is sucked through the slit 111, and when the flexible air pipe 120 is expanded, the fluid is expanded in the inner space of the pipe housing 110 and the fluid sucked inside the pipe through the slit 111. It is ejected into the housing 110. At this time, the slit 111 is preferably sprayed to form a spray angle of about 60 degrees with the hull surface 101.

On the other hand, in the case of using the valve 220 when driving the motor 250, the first rod 230 and the second rod 240 connected to the motor 250 is moved up and down in opposite directions to each other to move the piston When the first rod plate 220a side is lowered and compressed, the second rod side 220b is raised to compress the upper and lower portions with the slit 211 therebetween. When the valve is compressed at the same time up and down, the internal fluid is ejected to the outside through the slit 211. On the contrary, when the second rod 240 descends at the same time as the first rod 230 rises, the fluid contacting the slit 211 is sucked between the valves 220a and 220b.

At this time, it is preferable that the slit 211 formed in the pipe housing 210 sprays the fluid while forming an injection angle of about 60 ° with the hull surface 101.

On the other hand, the pipe housings of the present invention can be installed inside the hull while communicating with the outside in a slit between the hull wall surface.

The suction and ejection of the fluid using the flexible air pipe 120 or the valve 220 of the present invention as described above allows the fluid to be sucked and sprayed over the entire outer surface of the hull, and the fluid is sucked and the fluid is discharged at an optimum injection angle. Through the injection of, the fluid flowing along the hull surface is disturbed to suppress the generation of vortices on the hull surface, thereby reducing the frictional resistance.

In addition, when installed locally on the steering wheel of the ship, it is possible to control the fluid flow in the steering wheel, it is also possible to suppress the cavitation of the other.

As described above, according to the present invention, a method and apparatus for reducing drag by controlling turbulence of a ship's hull surface according to the present invention changes the flow field of turbulence through inhalation and injection of fluid by the action of a flexible air pipe or valve, By controlling the injection angle to reduce the frictional resistance, the generation of vortices on the hull surface is suppressed, resulting in the effect of reducing the current resistance on the operation of the ship.

In addition, by installing the drag reduction device of the ship using the flexible air pipe or valve locally to the steering wheel of the ship, it is also useful to be able to control the fluid flow in the steering wheel to suppress the cavitation of the other.

Claims (6)

In the drag reduction method by turbulence control of the hull surface of a ship, A method for reducing drag due to turbulence control of a ship's hull surface, characterized by reducing the frictional resistance by changing the flow field of the turbulent flow by inhaling and ejecting fluid flowing along the ship's hull surface and adjusting the injection angle with the hull surface. The method of claim 1, Drag reduction method by turbulence control of the hull surface of a ship, characterized in that the injection angle is 60 °. In the drag reduction device by turbulence control of the hull surface of a ship, A pipe housing 110 installed on the hull surface 101 of the vessel 100 and having a plurality of slits 111 formed thereon; A flexible air pipe 120 installed inside the pipe housing 110 to perform contraction and expansion by pumping air; And a pump 130 installed at a predetermined position within the hull to contract and expand the air pipe 120, and a pump 130 installed to enable air supply to the air pipe 120. The method of claim 3, wherein In the valve housings 220a and 220b installed above and below the slit 211 along the inside of the pipe housing 210 in which the plurality of slits 211 are formed, and the valves 220a and 220b. A motor 250 for driving the first and second rods 230 and 240 connected to the first and second rods 230 and 240 and the first and second rods 230 and 240 to drive the first and second rods 230 and 240. Drag reduction device by turbulence control of the ship's hull surface characterized in that consisting of. The method according to claim 3 or 4, The drag reduction device of the ship's hull surface turbulence control, characterized in that to control the local flow of the vessel 100 by locally installing the drag reduction device of the vessel to the bow portion 102 or the stern portion 103 . The method according to claim 3 or 4, Drag reduction device by the turbulent surface turbulence control of the ship, characterized in that the pipe housing 110 is located inside the hull.