KR101185419B1 - Cavitation protection propeller using waterjet - Google Patents

Abstract

The present invention relates to a cavitation prevention propeller using a water jet that can suppress the cavitation generated at the end of the propeller. The present invention includes a water jet injector for injecting a water jet, a water jet supply for supplying the water jet to the water jet injector, and an angle adjuster for adjusting the spraying direction of the water jet injector. The present invention sprays a water jet to the distal end of the propeller to reduce the propulsion efficiency of the propeller and suppress the cavitation causing mechanical failure of the propeller.

Description

Cavitation protection propeller using waterjet

The present invention relates to a cavitation prevention propeller using a water jet, and more particularly, to a cavitation prevention propeller that reduces cavitation when a propeller of a ship is rotated.

In general, a ship floats on water by buoyancy generated between the ship and water. Ships floating on the water are forwarded or retracted forward by receiving propulsion by propulsion equipment installed with propellers.

For example, propellers with propellers containing an engine and several wings are rotated by the engine. When the propeller is rotated by the engine, one side of the propeller pushes back the water and the other side of the propeller sucks in the water.

At this time, the surface of the water is pushed by the propeller is high pressure and the surface of the water is sucked by the propeller the pressure is lowered. This creates a pressure differential on the front and back of the propeller and the ship receives propulsion to move forward or backward.

Cavitation occurs at the distal end of the propeller when the propeller rotates quickly and when the propeller's rotation speed suddenly increases. Cavitation forms as if it is instantaneously circulating around the propellers, reducing the propeller's propulsion efficiency. In addition, when the cavitation is extinguished, the water vapor around the propeller changes to water, and the space around the propeller is momentarily reduced and the impact caused by the propeller is applied. Therefore, the propeller has a problem that the propulsion efficiency is lowered and mechanical failure is caused by the cavitation.

An object of the present invention is to provide a cavitation prevention propeller using a water jet to spray the water jet to increase the propulsion efficiency of the propeller and to reduce the cavitation.

The present invention provides a water jet injection unit including a nozzle for injecting a water jet from the wing surface of the propeller, a water jet supply unit for supplying the water jet to the water jet injection unit, and an angle adjustment unit for adjusting the angle of the nozzle. It provides a cavitation prevention propeller using a water jet containing.

The cavitation prevention propeller using the waterjet of the present invention suppresses the cavitation generated at the distal end of the propeller by using the waterjet supply unit and the waterjet injection unit for injecting the waterjet delivered from the waterjet supply unit.

In addition, the present invention effectively suppresses the cavitation generated at the distal end of the propeller by using an angle adjuster for adjusting the angle of the nozzle.

In addition, the present invention increases the propulsion efficiency of the vessel by suppressing the cavitation generated at the distal end of the wing.

1 is a front view showing an embodiment of a cavitation prevention propeller using a water jet according to the present invention.
2 is a cross-sectional view showing a cross-section of the cavitation prevention propeller using a water jet.
3 is a cross-sectional view showing an embodiment of a water jet supply unit.

1 is a front view showing an embodiment of the cavitation prevention propeller 100 using a water jet according to the present invention. 2 is a cross-sectional view showing a cross-section of the cavitation prevention propeller 100 using a water jet. 3 is a cross-sectional view showing an embodiment of the water jet supply unit 120.

1 to 3, the cavitation prevention propeller 100 using the water jet includes a water jet injection unit 110, a water jet supply unit 120, and an angle adjustment unit 130.

The water jet spraying unit 110 includes a nozzle 111 for spraying a water jet. The nozzle 111 is installed in the groove 141 portion formed at the end of the wing 140.

The water jet supplied from the water jet supply unit 120 is sprayed from the surface of the wing 140 to prevent the cavitation generated at the distal end of the wing 140.

The nozzle 111 is controlled by the angle adjusting unit 130 so as to spray the water jet toward a place where the pressure is reduced due to the occurrence of the cavitation generated at the distal end of the wing 140.

The nozzle 111 includes an adjusting device 113. The adjusting device 113 is installed on one side of the nozzle 111. The adjusting device 113 is controlled by the control unit 132 of the angle adjusting unit 130. Alternatively, the adjusting device 113 is controlled by the user. The adjusting device 113 adjusts the opening and closing degree of the water jet moving tube 112. Thus, the nozzle 111 is adjusted the speed of the water jet sprayed by the adjusting device 113.

The water jet injection unit 110 includes a water jet moving tube 112. Water jet moving tube 112 is a nozzle 111 is installed at the end and is installed inside the wing 140. At this time, the water jet moving tube 112 is installed corresponding to the curvature of the wing 140. The water jet supplied from the water jet supply unit 130 is moved to the nozzle 111 through the water jet moving tube 112.

The water jet moving tube 112 is installed inside the wing 140 to prevent the water jet moving tube 112 from being deformed due to the pressure generated while the wing 140 is rotated. Water jet moving tube 112 is installed in the plurality of wings 140 so as to cope with the cavitation generated in the wing 140 end portion. In addition, the water jet moving pipe 112 is installed on each wing 140.

The water jet moving tube 112 includes a material having a high strength to prevent the inside of the wing 140 from being damaged by the water jet being moved.

The wing 140 is rotated and the moving speed of water is increased by the rotational force of the wing 140. Increasing the speed of water decreases the water pressure. When the pressure of the water is lowered below the vapor pressure, the water is changed into water vapor and a phenomenon occurs such that the circumference of the wing 140 is empty. At this time, the water jet injection unit 110 prevents a phenomenon such as the circumference of the wing 140 is empty by spraying the water jet to the end portion of the wing 140.

Therefore, the cavitation generated at the distal end of the wing 140 is prevented and the propulsion efficiency of the ship is increased.

The water jet supply unit 120 includes a water supply unit 121. The water supply unit 121 is connected to the pressure generating unit 122 to supply water. At this time, the water supply unit 121 is installed on the surface of the vessel to supply water outside the vessel to the pressure generating unit 122. In addition, the water supply unit 121 may include a separate tank (not shown) in which water is stored to supply water to the pressure generating unit 122.

The water jet supply unit 120 includes a pressure generating unit 122. The pressure generating unit 122 is installed between the water jet moving tube 112 and the water supply unit 121. The pressure generator 122 applies a pressure to the water supplied from the water supply unit 121 and discharges it to the water jet moving tube 112.

At this time, the pressure generating unit 122 constantly controls the amount of the water jet supplied to the water jet moving pipe (112). In addition, the pressure generating unit 122 may control to vary the amount of the water jet supplied to the water jet moving pipe (112).

The pressure generator 122 is fastened to a rotating shaft (not shown) of the cavitation prevention propeller 100 using the water jet. At this time, the rotating shaft is formed inside the space, it is connected to the cavitation prevention propeller 100 using a water jet. In addition, the central portion of the cavitation prevention propeller 100 using the water jet is hollow and the water jet moving pipe 112 is connected.

Therefore, the water pressurized by the pressure generating unit 122 moves to the inner space of the rotating shaft. The water moves to the water jet moving tube 112 through the center of the cavitation prevention propeller 100 using the water jet.

Meanwhile, the pressure generator 122 may be coupled to a connection member (not shown) separately from the water jet moving tube 112. The connection member may transfer the water jet to the water jet moving tube 122.

At this time, the connecting member is inserted into the hollow portion of the cavitation prevention propeller 100 using the internal space and the water jet of the rotating shaft. The connection member may include a hose or the like coupled to the pressure generator 122.

The angle adjuster 130 includes a pressure sensor 131. A plurality of pressure sensors 131 are installed at the distal end of the wing 140 and are installed on each wing 140. The pressure sensor 131 detects that the pressure is changed by the cavitation caused by the rotation of the blade 140. The pressure sensor 131 measures the pressure at the end of the wing 140 and outputs a pressure signal to the controller 132.

The pressure sensor 131 outputs a pressure signal having a small output size when the pressure at the distal end of the wing 140 is reduced due to the phenomenon of cavitation.

The angle adjuster 130 includes a controller 132. The control unit 132 is installed in the wing 140 receives the pressure signals output from the plurality of pressure sensors 131. The control unit 132 receiving the plurality of pressure signals compares the respective pressure signals and outputs rotation data for determining the rotation direction and the rotation angle of the nozzle rotating device 133 to the nozzle rotating device 133.

The controller 132 is connected to the pressure sensor 131 and the nozzle rotating device 133 by wire to transmit and receive the pressure signal and the rotation data. In addition, the controller 132 may be wirelessly connected to the pressure sensor 131 and the nozzle rotating device 133 to transmit and receive the pressure signal and the rotation data.

The controller 132 determines whether a cavity phenomenon is generated based on the pressure signal. The controller 132 generates an operation signal when the cavity phenomenon occurs. The control unit 132 transmits the operation signal to the adjusting device 113. The adjusting device 113 receives the operation signal. The adjusting device 113 adjusts the opening degree of the water jet moving tube 112. Therefore, the adjusting device 113 controls the speed of the water sprayed from the nozzle 111 to remove the cavitation when the cavitation occurs.

The controller 132 transmits the operation signal to the pressure generator 122. The pressure generator 122 receives the operation signal. The pressure generator 122 varies the amount of water jet supplied to the water jet moving pipe 120. Therefore, the amount of the water jet supplied to the water jet injection unit 110 can be accurately controlled.

The angle adjuster 130 includes a nozzle rotating device 133. The nozzle rotating device 133 is installed below the nozzle 111. The nozzle rotator 133 rotates the nozzle 111 by receiving the rotation data output from the controller 132.

By the angle adjuster 130, the nozzle 111 is rotated in the direction of the pressure sensor 131 where the output of the pressure signal is low, thereby effectively suppressing the cavitation generated at the distal end of the wing 140.

As mentioned above, although the cavitation prevention propeller using the waterjet was demonstrated with reference to the Example of this invention, it is clear for those skilled in the art that correction, a change, and various deformation | transformation Example are possible without deviating from the idea of this invention.

100: cavitation prevention propeller using water jet
110: water jet injection unit
120: water jet supply
130: angle adjuster
140: wings

Claims (8)

A water jet spraying unit having a nozzle for spraying water jets on the wing surface of the propeller;
A water jet supply unit supplying the water jet to the water jet injection unit;
A plurality of pressure sensors installed at the distal end of the propeller blades to measure the pressure at the distal end of the propeller blades and output a pressure signal, a controller for outputting rotation data based on the pressure signal, and receiving the rotation data It includes an angle adjusting unit having a nozzle rotating device for adjusting the angle of the nozzle by rotating the nozzle,
The pressure sensor outputs the pressure signal having a small output size to the controller when the pressure of the propeller blade end portion is lowered,
And the control unit compares the pressure signal and outputs the rotation data capable of rotating the nozzle in a direction in which the pressure sensor outputting the pressure signal having a small output size is located.
The method according to claim 1,
The water jet injection unit,
The nozzle is installed at the distal end of the propeller blades cavitation prevention propeller using a water jet comprising a plurality of water jet moving pipe is installed inside the propeller blades.
The method according to claim 2,
The water jet moving pipe is a cavitation prevention propeller using a water jet installed to correspond to the curvature of the propeller blades.
The method according to claim 1,
The nozzle is cavitation prevention propeller using a water jet including a control device for adjusting the speed of the water jet is injected through the nozzle.
The method according to claim 1,
The water jet supply unit,
A water supply unit for supplying water,
Cavitation prevention propeller using a water jet comprising a pressure generating portion for adjusting the amount of water to be sent to the water jet injection by applying pressure to the water supplied from the water supply.
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