KR101516204B1 - A winch for cable and a launching system of robot for working on ship - Google Patents

Abstract

A cable launch winch and a robotic launch system for hull wall work are disclosed. A cable winch according to an embodiment of the present invention includes a frame portion; A drum portion supported by the frame portion, wherein the cable is wound or unwound; And a tension adjusting unit which is supported on the frame portion and is disposed apart from the drum portion to support the cable and adjusts the tension of the cable, wherein the tension adjusting unit is configured to adjust the tension of the cable when the cable is wound on the drum portion, , So that the tension of the cable located between the drum portion and the tension adjusting unit is kept constant.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a winch for a cable,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a winch for a cable and a robots launching system for hull wall work.

The walls of the hull are always immersed in seawater, and many types of foreign matter are often attached. These foreign bodies mainly consist of biofouling phenomena caused by attached organisms such as barnacles, auricles, and sponges.

The phenomenon of biofouling causes problems such as increasing the resistance between the wall surface of the hull and seawater, or blocking the flow of seawater in the hull.

For example, in the case of a bio-sticking phenomenon on a wall surface of a hull, the operating efficiency of the ship may be reduced or the maximum speed of the ship may be reduced. In the case where bio-sticking phenomenon occurs on the inner surface of the inlet and outlet pipes of the cooling system using seawater, smooth flow of seawater may be obstructed or blocked.

As described above, since the biofouling phenomenon causes various problems, various methods have been attempted to solve the problems caused by the biofouling phenomenon in the case of a ship.

In the case of ships, it is necessary to move the hull to a dry dock to remove the attachment creature, or to apply toxic antifouling paint to the wall of the hull, And the like are used.

However, it takes a lot of time and money to remove the attached organisms by moving the hull to the dry poison, and there is a problem that the ship can not be used while removing the attached organisms.

In addition, antifouling paints include antifoulant which interferes with the attachment of living things. Tributyltin (TBT), which is widely used as an antifouling agent, causes destruction or disturbance of a marine ecosystem.

Accordingly, research and development on a method of moving a cleaning device for physically removing adhering organisms attached to a wall surface of a hull to move along the wall of the hull are underway.

Currently, robots such as ROV (Remotely Operated Vehicle) are being used for cleaning the walls of the hull.

In order to clean the wall surface of the hull, when the robot is launched toward the wall surface of the hull, communication with the robot is required to supply power to the robot and control the robot. Accordingly, a tether cable, which is a composite cable in which a power cable and a communication optical cable are combined, is connected to the robot.

However, since the tether cable is embedded in the optical cable, the tether cable is twisted to the winch when the tether cable is wound around the winch or the tether cable is unwound from the winch because the tether cable can not be subjected to a large tension in launching and retrieving the robot. .

[Patent Document 1] Korean Patent Publication No. 10-2008-0093536 (published on October 22, 2008)

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a cable winch and a robot launching system for hull wall work which can prevent a tether cable connected to a robot from being twisted to a winch in launching and recovering the robot.

According to an aspect of the present invention, A drum portion supported on the frame portion, the cable portion being wound or unwound; And a tension adjusting unit which is supported by the frame part and is disposed to be spaced apart from the drum part to support the cable and adjusts the tension of the cable, wherein the tension adjusting unit includes: A cable winch for keeping the tension of the cable located between the drum portion and the tension adjusting unit constant when the cable is unwound from the drum portion can be provided.

The tension adjusting unit includes: a pair of rotating roller parts arranged to face each other with the cable interposed therebetween, the pair of rotating roller parts being in close contact with the cable; And a roller driving unit connected to any one of the pair of rotating roller units to provide rotational driving force.

The pair of rotating roller units may include: a driving roller connected to the roller driving unit and rotating; And a driven roller which is disposed to face the driving roller with the cable interposed therebetween, and which is rotated by friction due to the winding and unwinding of the cable in close contact with the cable.

The outer circumferential surface of the driving roller and the driven roller may be provided with a groove into which the cable is inserted to increase frictional force with the cable.

The roller driving unit may rapidly rotate the driving roller when the cable is loosened by the drum unit rather than when the cable is wound around the drum unit to keep the tension of the cable constant.

And a cable aligning unit supported on the frame portion and connected to the tension adjusting unit to reciprocate the tension adjusting unit along the central axis direction of the drum portion and to wind the cable in the multi- have.

Wherein the cable alignment unit comprises: a guide portion arranged to be long along the central axis direction of the drum portion and guiding the reciprocating motion of the tension adjusting unit; And a movement driving unit connected to any one of the tension adjusting unit and the guide unit and reciprocating the tension adjusting unit along the guide unit.

The drum unit includes: a drum driving shaft connected to the frame unit; A rotary drum connected to the drum drive shaft and rotating, the cable being wound or unwound; And a drum driving unit connected to the drum driving shaft to rotate the drum driving shaft.

Grooves in which the cables are inserted may be continuously formed on the outer circumferential surface of the rotary drum in a threaded manner.

The cable may be a tether cable including a power cable for supplying power to the robot and an optical cable for communicating with the robot.

And a slip ring connected to one end of the tether cable to supply power to the robot during a rotational movement of the drum and to enable communication with the robot.

According to another aspect of the present invention, there is provided a work robot, A cable connected at one end to the robot to supply power to the robot and communicate with the robot; And a cable winch which winds the other end of the cable and uncovers the cable wound around the robot when the robot is launched, the cable winch comprising: a frame part; A drum portion supported by the frame portion, wherein the cable is wound or unwound; And a tension adjusting unit that is supported by the frame unit and is spaced apart from the drum unit to support the cable and adjust the tension of the cable.

The tension adjusting unit includes: a pair of rotating roller parts arranged to face each other with the cable interposed therebetween, the pair of rotating roller parts being in close contact with the cable; And a roller driving unit connected to any one of the pair of rotating roller units to provide rotational driving force.

The pair of rotating roller units may include: a driving roller connected to the roller driving unit and rotating; And a driven roller which is disposed to face the driving roller with the cable interposed therebetween and which is in close contact with the cable and is rotated by friction due to winding and unwinding of the cable. In order to keep the tension of the cable constant , The driving roller can be rotated rapidly when the cable is unwound by the drum rather than when the cable is wound around the drum.

The outer circumferential surface of the driving roller and the driven roller may be provided with a groove into which the cable is inserted to increase frictional force with the cable.

The cable winch includes a cable harness supported by the frame portion and connected to the tension adjusting unit to reciprocally move the tension adjusting unit along the central axis of the drum portion and to wind the cable to the drum portion in a multi- Unit. ≪ / RTI >

Wherein the cable alignment unit comprises: a guide portion arranged to be long along the central axis direction of the drum portion and guiding the reciprocating motion of the tension adjusting unit; And a movement driving unit connected to any one of the tension adjusting unit and the guide unit and reciprocating the tension adjusting unit along the guide unit.

The drum unit includes: a drum driving shaft connected to the frame unit; A rotary drum connected to the drum drive shaft and rotating, the cable being wound or unwound; And a drum driving part connected to the drum driving shaft to rotate the drum driving shaft. Grooves for inserting the cables may be continuously formed on the outer circumferential surface of the rotating drum in a threaded manner.

The robot includes a robot body; An attitude conversion unit provided in the robot body for converting the attitude of the robot body by moving the center of buoyancy of the robot body in water; And a propulsion unit which is provided on the robot body and moves the robot body whose posture is changed to the wall surface of the hull.

Wherein the posture changing unit includes: at least a pair of storage tanks provided to be spaced apart from each other in the robot body; And a fluid passage connected to the pair of storage tanks for communicating the at least one pair of storage tanks, wherein fluid is supplied to the other storage tank from one of the at least one pair of storage tanks, So that the center of buoyancy of the robot main body can be moved.

The robot main body may be rotated about a plane intersecting line formed by the pair of storage tanks crossing the imaginary line connecting the pair of storage tanks.

The pair of storage tanks is constituted by an air cylinder, and seawater can be stored in the air cylinder.

The propulsion unit may be disposed on the upper surface of the robot body to move the robot body to the wall surface of the hull when the posture of the robot body is converted to be vertically upright in a horizontal state by the posture changing unit have.

The robot includes a traveling unit provided at a lower portion of the robot body and allowing the robot body to travel along a wall surface of the ship body; And a cleaning unit provided at one side of the robot body for removing foreign matter adhering to a wall surface of the hull.

Embodiments of the present invention can prevent the cable from being twisted to the drum portion where the cable is wound or unwound by providing the tension adjusting unit for adjusting the tension of the cable.

FIG. 1 is a schematic view illustrating a process of launching a robot for hull wall work according to an embodiment of the present invention.
2 is a perspective view showing an upper part of a robot for hull wall work according to an embodiment of the present invention.
3 is a perspective view illustrating a rear surface of a robot for hull wall work according to an embodiment of the present invention.
4 and 5 are views showing the posture changing operation of the robot for working the hull wall surface by the posture changing unit according to the embodiment of the present invention.
6 is a sectional view showing a tether cable according to an embodiment of the present invention.
7 is a perspective view showing a winch for a cable according to an embodiment of the present invention.
8 and 9 are views showing the operation of the tension adjusting unit according to an embodiment of the present invention.
10 and 11 are views showing the operation of the cable alignment unit according to an embodiment of the present invention.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

Hereinafter, the present invention will be described in detail with reference to the preferred embodiments of the present invention with reference to the accompanying drawings. Like reference symbols in the drawings denote like elements.

2 is a perspective view showing an upper part of a robot for hull wall work according to an embodiment of the present invention. FIG. 3 is a perspective view of a robot for working hull wall work according to an embodiment of the present invention. 4 and 5 are views showing a posture changing operation of the robot for working the hull wall surface by the posture changing unit according to the embodiment of the present invention, FIG. 6 is a cross-sectional view showing a tether cable according to an embodiment of the present invention, FIG. 7 is a perspective view showing a winch for a cable according to an embodiment of the present invention, FIGS. 8 and 9 are views 10 and 11 are views showing the operation of the cable alignment unit according to an embodiment of the present invention.

Referring to FIG. 1, a robot launching system for hull wall work according to an embodiment of the present invention includes a robot 200 for hull wall work, and one end connected to the robot 200 to supply power to the robot 200, A tether cable 400 for allowing the tether cable 400 to communicate with the tether cable 200 and a cable winch for unwinding the tether cable 400 wound at the other end of the tether cable 400 and wound at the time of launching the robot 200 300).

The robot control system for a hull wall work according to an embodiment of the present invention is configured to move the robot 200 for hull wall work to the wall surface 110 of the hull when the foreign matter adheres to the wall surface 110 of the hull, After attaching to the wall surface 110, the wall surface 110 of the hull is cleaned.

At this time, the robot 200 for a hull wall work is launched from the shore or another ship adjacent to the ship 100 on which the foreign matter is adhered to the wall surface 110 of the hull. The tether cable 400 connected to the robot 200 is used for a cable Is wound on the winch (300) and unrolled in the cable winch (300) simultaneously with the launching of the robot (200). When the cleaning operation for the wall surface 110 of the hull is completed, the tether cable 400 is wound on the cable winch 300 at the same time as the robot 200 is recovered.

Hereinafter, a robot launching system for hull wall surface work in accordance with an operation of recovering the robot 200 for a hull wall work to the wall surface 110 of the hull and the wall surface 110 of the hull will be described.

2 to 5, a hull wall work robot 200 according to the present embodiment includes a robot body 210 and a robot body 210. The robot body 210 includes a robot body 210, A cleaning unit 250 provided at one side of the robot main body 210 for removing foreign matter adhered to the wall surface of the hull (110 in FIG. 1) An attitude conversion unit 260 provided in the robot body 210 for changing the attitude of the robot body 210 by moving the center of buoyancy of the robot body 210 in the water, And a propulsion unit 230 for moving the robot body 210 to a wall surface of the hull (110 in Fig. 1).

2 and 3, the robot body 210 has a waterproof structure in which seawater is not introduced into the robot body 210 when the robot body 210 is operated underwater.

A power supply unit (not shown) and a control unit (not shown) are provided in the robot body 210 to provide power to the traveling unit 240 and the cleaning unit 250, which will be described later.

Meanwhile, the hull wall work robot 200 according to the present embodiment should be attached to the wall surface (110 of FIG. 1) of the hull to perform cleaning work of foreign substances adhered to the wall surface (110 of FIG. 1) of the hull.

Accordingly, the hull wall work robot 200 according to the present embodiment is launched at a position adjacent to the ship (100 in Fig. 1), and then is moved to the wall surface (110 in Fig. 1) Unit 260 and a propulsion unit 230. [

Particularly, after the hull wall work robot 200 according to the present embodiment is launched, after the posture is converted by the posture changing unit 260, the robot 200 is moved to the wall surface (110 in Fig. 1) of the hull by the propelling unit 230 .

Hereinafter, the attitude conversion unit 260 related to the attitude conversion of the robot main body 210 will be described first. In particular, the posture change of the robot main body 210 will be described by way of example when the posture is changed from a horizontal state to a vertical state (Z direction) after launching.

In this embodiment, the attitude conversion unit 260 serves to convert the posture of the robot body 210 in the horizontal state (X direction) to a vertical state (Z direction) standing up in water.

That is, the attitude conversion unit 260 is provided in the robot main body 210 and changes the attitude of the robot main body 210 by moving the buoyant center of the robot main body 210 in water.

The posture changing unit 260 serves to change the posture of the robot body 210 by moving the buoyancy center of the robot body 210 in water.

2 and 3, the attitude conversion unit 260 includes at least a pair of storage tanks 261 and 262 spaced apart from each other in the robot body 210, at least a pair of storage tanks 261 and 262 connected to the pair of storage tanks 261 and 262, And a fluid passage 263 for communicating the pair of storage tanks 261 and 262 with each other.

Preferably, the pair of storage tanks 261 and 262 are provided so as to be opposed to the front and rear sides or both sides of the robot body 210, respectively.

In this embodiment, the pair of the storage tanks 261 and 262 is constituted by an air cylinder, and seawater is stored in the inside of the air cylinder.

Specifically, when a pair of storage tanks 261 and 262 are arranged in pairs facing each other in front of and behind the robot body 210, a pair of the storage tanks 261 and 262 are disposed in front of and behind the robot body 210 The robot main body 210 is rotated about a plane intersecting line (Y axis) formed by a pair of storage tanks 261 and 262 crossing an imaginary line (X axis) connecting the storage tanks 261 and 262.

That is, the posture of the robot main body 210 is converted so as to stand upright in the vertical state (Z direction) in the horizontal state (X direction) while the front of the robot body 210 is heard.

On the other hand, when the posture of the robot main body 210 is to be rotated right and left in the longitudinal direction of the robot main body 210 along the central axis (X axis), the storage tanks are arranged to be opposed to both sides of the robot main body 210 can do.

A plurality of pairs of storage tanks 261 and 262 are disposed on the robot body 210 to facilitate movement of the center of buoyancy of the robot body 210.

One of the storage tanks 261 and 262 is communicated by the fluid passage 263 and one storage tank 261 supplies the seawater to another storage tank 262 through the fluid passage 263, And receives the seawater from the tank 262.

An operation of converting the posture of the robot body 210 by moving the buoyancy center of the robot body 210 using the above described pair of storage tanks 261 and 262 and the posture changing unit 260 including the fluid channel 263 As follows.

1, the hull wall work robot 200 according to the present embodiment is to be launched from the shore adjacent to the ship 100 and then moved to the wall surface (110 in Fig. 1) of the hull.

Immediately after the launching, the robot main body 210 maintains a horizontal state (X-axis direction) with respect to the sea surface as shown in Fig. Then, the robot body 210 is rotated as shown in Fig. 5 in order to move to the wall surface (110 in Fig. 1) of the hull, and the posture is changed to the vertical state (Z direction) on the sea surface.

In at least one pair of storage tanks 261 and 262 disposed opposite to the front and rear of the robot body 210, seawater is initially stored so that the center of gravity of the robot body 210 matches the center of buoyancy.

5, in order to change the attitude of the robot main body 210 in a vertical state (Z direction) in a horizontal state (X-axis direction) with respect to the sea surface, The seawater stored in at least one storage tank 261 is transferred to at least one storage tank 272 disposed at the rear of the robot body 210.

As the seawater stored in the front of the robot body 210 moves backward as described above, the buoyancy center of the robot body 210 moves to the rear side of the robot body 210, and the robot body 210 rotates, (Z direction).

As described above, the attitude of the robot body 210 can be easily changed by moving the center of buoyancy of the robot body 210 by using the posture conversion unit 260.

After the posture of the robot main body 210 stands upright in the vertical direction (Z direction) in the horizontal state (X direction), the propulsion unit 230 drives the robot main body 210 to move the wall surface 110) direction.

2, in this embodiment, the propulsion unit 230 is disposed on the upper surface of the robot main body 210 and includes a propulsive force for moving the robot main body 210 in the direction of the wall surface of the hull (110 in Fig. 1) .

The robot body 210 is moved in the direction of the wall of the hull (110 in Fig. 1) by operating the propulsion unit 230 when the posture is changed in the vertical state (Z direction) .

A plurality of propellers such as a propeller for controlling the posture of the robot body 210 and a propeller for moving the robot body 210 have been conventionally required. In this embodiment, however, the posture changing unit 260 is used, The robot body 210 is moved to the wall surface of the hull by the propelling unit 230 so that the number of the propulsion units 230 can be reduced. The cost can be reduced.

When the robot body 210 is moved to the wall surface (110 in Fig. 1) of the hull by using the attitude conversion unit 260 and the propelling unit 230 as described above, the robot body 210 is moved to the wall surface (110 in FIG. 1) and removes foreign matter adhering to the wall surface of the hull (110 in FIG. 1).

The travel unit 240 serves to cause the robot main body 210 to travel along the wall surface (110 in Fig. 1) of the hull.

1, the traveling unit 240 is provided at a lower portion of the robot body 210 to move the robot body 210 along the wall surface 110 of the hull.

The traveling unit 240 includes a robot body attachment portion (not shown) so that the robot body 210 can maintain a state where the robot body 210 is attached to the wall surface 110 of the hull.

The robot main body attachment portion may be formed of a permanent magnet or an electromagnet and an electromagnetic attraction force acts between the robot main body 210 and the wall surface 110 of the hull to attach the robot main body 210 to the wall surface 110 of the hull.

The cleaning unit 250 removes foreign matter adhering to the wall surface 110 of the hull while the robot body 210 travels along the wall surface 110 of the hull in a state where the robot body 210 is attached to the wall surface 110 of the hull It plays a role.

3, the cleaning unit 250 includes a brush 251 provided on one side of the robot main body 210, in particular, in front of the robot main body 210 to remove foreign matter adhered to the wall surface of the hull (110 in FIG. 1) However, the present invention is not limited to this, and any means can be used as long as it can remove foreign matter adhered to a wall surface (110 in FIG. 1) such as a water jet (not shown).

A tether cable 400 is connected to the robot main body 210 and the tether cable 400 supplies power to the robot main body 210 and enables communication with the robot main body 210.

6, the tether cable 400 includes a power cable 410 for supplying power to the robot main body 210 and a communication optical cable for communicating with the robot main body 210 for controlling the robot main body 210 430).

As shown in FIGS. 2 and 3, the tether cable 400 may be connected to the rear of the robot body 210.

The tether cable 400 can not apply a large tension to the tether cable 400 in launching and retrieving the robot 200 because the telecommunication cable 430 is embedded therein.

Accordingly, when the tether cable 400 is wound around the winch or unwound by the winch, the tether cable 400 is twisted to the winch. In this embodiment, a cable winch 300 is provided to keep the tension applied to the tether cable 400 constant in order to prevent the tether cable 400 from being twisted in the winch.

7 to 11, the winch 300 for a cable according to the present embodiment includes a frame 310, a drum 310 supported on the frame 310, and a tether cable (400 of FIG. 6) A tether cable 330 which is supported on the frame 310 and spaced apart from the drum 330 to support the tether cable 400 and wound on the drum 330 or unwound from the drum 330; And a tension adjusting unit 350 that adjusts the tension of the elastic member 400.

The frame unit 310 supports elements constituting the cable winch 300 such as the drum unit 330 and the tension adjusting unit 350 and has a function of attaching foreign substances to the wall surface of the hull And is installed on a shore or other ship adjacent to the ship 100.

The drum portion 330 is installed on one side of the frame portion 310 so that the tether cable 400 is wound or unwound.

The tether cable 400 is loosened by the drum 330 when the robot is launched and the tether cable 400 is wound around the drum 330 when the robot is recovered.

The drum unit 330 according to the present embodiment includes a drum driving shaft 331 connected to the frame unit 310 and a rotary drum 331 connected to the drum driving shaft 331 to rotate and rotate the tether cable 400. [ And a drum driving unit 335 connected to the drum driving shaft 331 to rotate the drum driving shaft 331. [

The rotary drum 333 is formed in a cylindrical shape and is installed in the frame portion 331 so that the tether cable 400 is wound or unwound as it is rotated. At this time, the rotary drum 333 may be formed in a cylindrical shape, but any shape may be used if the tether cable 400 is formed to be wound or unwound.

A groove 337 into which the tether cable 400 is inserted is continuously formed on the outer circumferential surface of the rotary drum 331 in the form of a screw.

When the tether cable 400 is wound around the rotary drum 333 in multiple stages using a cable alignment unit 370 to be described later, the tether cable 400 is sequentially wound on the rotary drum 333 in an aligned state To be released sequentially from the rotary drum 333.

The rotary drum 333 is connected to the drum driving shaft 331 and is rotated by a drum driving part 335 for rotating the drum driving shaft 331.

7, both end portions of the drum driving shaft 331 are supported by the frame portion 310, and the drum driving shaft 331 is inserted into the rotary drum 333. As shown in Fig. The drum driving shaft 331 is connected to the drum driving part 335 provided on one side of the frame part 310.

Accordingly, the drum driving unit 335, that is, the drum driving motor rotates the drum driving shaft 331 and the rotating drum 333 clockwise or counterclockwise to wind the tether cable 400 on the rotating drum 333, 333) of the tether cable (400).

On the other hand, when the tether cable 400 is wound on the rotary drum 333 or the tether cable 400 is loosened on the rotary drum 333, power is supplied to the robot 200 during the rotary motion of the rotary drum 333 The cable winch 300 according to the present embodiment further includes a slip ring 390 provided on one side of the rotary drum 333 in order to enable communication with the robot 200 at the same time.

In particular, the slip ring 390 may be inserted into one end of the drum drive shaft 331 and connected to one end of the tether cable 400.

As described above, when the tether cable 400 is unwound from the rotary drum 333 or the tether cable 400 is wound around the rotary drum according to the launching and returning of the robot 200, It is necessary to prevent a large tension from being applied to the tether cable 400 due to the optical cable 430.

Therefore, in this embodiment, the tension adjusting unit 350 that keeps the tension of the tether cable 400 constant is provided.

When the tether cable 400 is unwound from the drum part 330 or wound around the drum part 330 when the robot 200 is launched and recovered, the tension adjusting unit 350 adjusts the tension of the drum part 330, And serves to maintain the tension of the tether cable 400 positioned between the units 350 constant.

The tension adjusting unit 350 according to the present embodiment includes a pair of tether cables 400 spaced apart from the drum 330 and disposed to face each other with the tether cable 400 interposed therebetween, And a roller driving unit 355 connected to any one of the rotating roller unit 351 and the pair of rotating roller units 351 to provide rotational driving force.

The pair of rotating roller portions 351 closely contact the tether cable 400 and rotate to control the tension applied to the tether cable 400.

The pair of rotating roller units 351 includes a driving roller 352 which is in tight contact with the tether cable 400 and is connected to the roller driving unit 353 and rotates, And a driven roller 353 which is arranged to face the tether cable 400 and is rotated by friction caused by winding and unwinding of the tether cable 400.

Here, the roller driving unit 355 may be configured as a driving motor connected to the driving roller 352 to rotate the driving roller 352. That is, the drive roller 352 is directly connected to the drive motor to directly control the rotation direction and the rotation speed of the drive roller 352.

The driven roller 353 is rotated by friction with the tether cable 400 as the driving roller 352 is rotated.

The tether cable 400 and the drive roller 352 and the drive roller 352 can be precisely controlled in order to precisely control the length of the tether cable 400 that is released or wound by the rotation of the drive roller 352 and the driven roller 353. [ 10 and 11, in order to increase the frictional force between the driven roller 353 and the outer peripheral surface of the drive roller 352 and the driven roller 353, that is, the surface on which the tether cable 400 is in contact, Thereby forming grooves 352a and 353a, respectively.

Since the tether cable 400 is loosened or wound in a state of being inserted into the grooves 352a and 353a of the driving roller 352 and the driven roller 353, It is possible to prevent the roller 353 from slipping on the outer peripheral surface.

The rotation speed of the drive roller 352 is different between when the robot 200 is launched and when the robot 200 is withdrawn so as to keep the tension applied to the tether cable 400 constant.

For example, as shown in FIG. 8, when the robot 200 is launched to the wall surface (110 of FIG. 1) of the hull, the tether cable 400 increases and the tension applied to the tether cable 400 increases due to the self weight of the tether cable 400. This increases the rotation speed of the rotating drum 333 to increase the tether cable 400 ) At a faster rate.

As the tether cable 400 is released from the rotary drum 333 at a high speed in the case of launching the robot 200 to the wall surface of the hull (110 in Fig. 1), the rotation speed of the drive roller 352 is rotated It is necessary to further increase the number of pulleys released by the drum 333 corresponding to the length of the tether cable 400.

9, when the robot 200 is withdrawn from the wall surface (110 in FIG. 1) of the hull, the tether cable 400 unwound to the wall surface of the hull (110 in FIG. 1) 333 and the tension of the tether cable can be increased by the reaction force against the force of pulling the tether cable 400 by the rotary drum 333.

Therefore, in order to prevent the tension applied to the tether cable 400 from increasing, when the robot 200 is to be recovered, the rotary drum 333 is rotated more slowly than when the robot 200 is launched. Therefore, the rotational speed of the driving roller 352 is rotated at a slower speed than when the robot 200 is driven when the robot 200 is recovered.

In the cable winch 300 according to the present embodiment, in particular, when the robot 200 is to be recovered from the wall surface (110 in Fig. 1) of the hull, the tether cable 400 is connected to the rotary drum 333 in multi- And a cable alignment unit 370 so as to be wound and aligned.

10 and 11, both ends of the cable aligning unit 370 are supported by the frame unit 310 and are connected to the tension adjusting unit 350 so that the tension adjusting unit 350 is rotated in the direction of the drum driving shaft 331 So that the tether cable 400 is wound around the rotary drum 333 in multiple stages.

The cable aligning unit 370 may include a guide portion connected to the tension adjusting unit 350 and disposed to be long along the central axis direction of the drum portion 330 to guide the reciprocating motion of the tension adjusting unit 350 And a movement driving unit 373 connected to one of the tension adjusting unit 350 and the guide unit 371 and reciprocating the tension adjusting unit 350 along the guide unit 371.

The guide portion 371 is arranged to be long in parallel with the central axis direction of the drum portion 330, that is, the direction of the drum driving shaft 331, and serves to guide the reciprocating motion of the tension adjusting unit 350.

The guide unit 371 may be a ball screw coupled to the tension adjusting unit 350 and causing the tension adjusting unit 350 to reciprocate in the direction of the drum driving shaft 331 as it rotates.

The movement driving unit 373 may include a driving motor connected to the ball screw to rotate the ball screw.

10, when the robot 200 is withdrawn from the wall surface (110 of FIG. 1) of the hull, in a state in which the tension adjusting unit 350 is disposed on the left side of the rotary drum 333, The tenter cable 400 is sequentially wound on the rotary drum 333 while rotating the guide unit 371 which is a ball screw to the right side of the rotary drum 333 as shown in the drawing.

Then, the tension adjusting unit 350 is reciprocated along the guide portion 371 by the above-described operation to wind the tether cable 400 to the rotary drum 333 in multiple stages.

The grooves 337 are continuously formed on the outer circumferential surface of the rotary drum 333 so that the tether cable 400 can be sequentially aligned and wound on the rotary drum 333 as described above.

The operation of the robotic launch system for hull wall work according to an embodiment of the present invention will now be described.

Referring to FIG. 1, a robot 200 connected to a tether cable 400 is launched from a shore or another ship 100 adjacent to a ship 100 having a foreign matter attached to a wall surface 110 of the ship.

The posture of the robot 200 should be changed from a horizontal state (X direction) to a standing vertical state (Z direction) in order to move the launched robot body 210 to the wall surface 110 of the hull.

5, in order to move the buoyancy center of the robot body 210, the seawater is moved from the storage tank 271 provided in front of the robot body 210 to the storage tank 272 provided at the rear side .

The robot body 210 is moved in the direction of the wall surface (110 in FIG. 1) of the hull by the propelling unit 230 after converting the launched robot body 210 into the upright vertical state (Z direction).

The robot 200 moved in the direction of the wall surface of the hull (110 in FIG. 1) travels along the wall surface of the hull (110 in FIG. 1) while being attached to the wall surface (110 in FIG.

The robot 200 moves along the wall surface of the hull (110 in Fig. 1), and removes foreign matter adhering to the wall surface (110 in Fig. 1) of the hull using the cleaning unit 250. [

The tether cable 400 for supplying power to the robot 200 and communicating with the robot 200 in launching the robot 200 to the wall of the hull (110 in Fig. 1) The tension applied to the tether cable 400 must be kept constant.

Therefore, when the robot 200 is driven to the wall surface (110 of FIG. 1) of the hull, when the tether cable 400 is rotated by rotating the rotary drum 333, the driving roller 352 of the tension adjusting unit 350, The tension applied to the tether cable 400 between the rotary drum 333 and the driving roller 352 is kept constant.

When the rotary drum 333 is rotated to wind the tether cable 400 in the recovery of the robot 200 from the wall surface 110 of the hull (110 in Fig. 1), the driving roller 352 of the tension control unit 350, The tension applied to the tether cable 400 between the rotary drum 333 and the driving roller 352 is kept constant.

1) than when the robot 200 is retracted from the wall surface of the hull (110 in Fig. 1) when the robot 200 is launched to the wall surface of the hull (110 in Fig. 1) The rotation speed of the motor is increased.

In this embodiment, when the tether cable 400 is wound around the rotary drum 333, the tension adjusting unit 350 is arranged so that the tether cable 400 can be wound around the rotary drum 333 in a multi- And a cable aligning unit 370 that reciprocates in the direction of the drum drive shaft 331 is provided.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

100: ship 110: hull wall
200: robot 210: robot body
230: propelling unit 240: driving unit
250: Cleaning unit 260: Posture conversion unit
300: winch for cable 310: frame part
330: drum portion 331: drum driving shaft
333: rotating drum 335: drum driving part
337: Groove 350: Tension control unit
351: a pair of rotating roller parts 352:
353: driven roller 355: roller driving part
370: cable alignment unit 371:
373: Movement driving unit 390: Slip ring
400: Tether cable

Claims (24)

A drum portion supported by the frame portion, wherein the cable is wound or unwound;
A tension regulating unit supported on the frame portion and spaced apart from the drum portion to support the cable and adjust tension of the cable located between the drum portion and the drum portion when the cable is wound around the drum portion; And
And a movement driving part which is supported by the frame part and is arranged along the central axis direction of the drum part and is connected to the guide part to which the tension adjusting unit is coupled and reciprocates the tension adjusting unit along the guide part And a cable aligning unit for reciprocating the tension adjusting unit along the guide unit so as to wind the cable in the multi-stage to the drum unit or to sequentially unwrap the cable wound in the multi-stage in the drum unit,
The tension adjusting unit includes:
A pair of drive rollers and driven rollers arranged to face each other with the cable interposed therebetween, and rotated in close contact with the cable; And
And a roller driving unit connected to the driving roller to provide a rotational driving force and to rapidly rotate the driving roller when the cable is loosened by the drum unit rather than when the cable is wound around the drum unit. The method according to claim 1,
On the outer peripheral surface of the drive roller and the driven roller,
And a groove into which the cable is inserted to increase a frictional force with the cable is formed. The method according to claim 1,
The drum unit,
A drum driving shaft connected to the frame portion;
A rotary drum connected to the drum drive shaft and rotating, the cable being wound or unwound; And
And a drum driving part connected to the drum driving shaft to rotate the drum driving shaft. The method of claim 3,
On the outer peripheral surface of the rotary drum,
Wherein a groove into which the cable is inserted is continuously formed in a threaded shape. The method according to claim 1,
The cable,
A winch for a cable which is a tether cable including a power cable for supplying power to the robot and an optical cable for communicating with the robot. 6. The method of claim 5,
And a slip ring provided on the drum unit and connected to one end of the tether cable to supply power to the robot during a rotational movement of the drum unit and enable communication with the robot. Work robots;
A cable connected at one end to the robot to supply power to the robot and communicate with the robot; And
And a cable winch wound around the other end of the cable,
The cable winch includes:
A drum portion supported by the frame portion, wherein the cable is wound or unwound;
A tension regulating unit supported on the frame portion and spaced apart from the drum portion to support the cable and adjust tension of the cable located between the drum portion and the drum portion when the cable is wound around the drum portion; And
And a movement driving part which is supported by the frame part and is arranged along the central axis direction of the drum part and is connected to the guide part to which the tension adjusting unit is coupled and reciprocates the tension adjusting unit along the guide part And a cable aligning unit for reciprocating the tension adjusting unit along the guide unit so as to wind the cable in the multi-stage to the drum unit or to sequentially unwrap the cable wound in the multi-stage in the drum unit,
The tension adjusting unit includes:
A pair of drive rollers and driven rollers arranged to face each other with the cable interposed therebetween, and rotated in close contact with the cable; And
And a roller driving unit connected to the driving roller to provide a rotational driving force and to rapidly rotate the driving roller when the cable is loosened by the drum unit rather than when the cable is wound around the drum unit. . 8. The method of claim 7,
On the outer peripheral surface of the drive roller and the driven roller,
And a groove into which the cable is inserted is formed to increase a frictional force with the cable. 8. The method of claim 7,
The drum unit,
A drum driving shaft connected to the frame portion;
A rotary drum connected to the drum drive shaft and rotating, the cable being wound or unwound; And
And a drum driving part connected to the drum driving shaft to rotate the drum driving shaft,
On the outer peripheral surface of the rotary drum,
And a groove into which the cable is inserted is continuously formed in a threaded shape. 8. The method of claim 7,
The robot includes:
Robot body
An attitude conversion unit provided in the robot body for converting the attitude of the robot body by moving the center of buoyancy of the robot body in water; And
And a propulsion unit provided on the robot body for moving the robot body whose posture is changed to the wall surface of the hull. 11. The method of claim 10,
The posture changing unit
At least a pair of storage tanks disposed apart from each other in the robot body; And
And a fluid channel connected to the pair of storage tanks for communicating the at least one pair of storage tanks,
And moving the buoyancy center of the robot body by moving fluid from one of the at least one pair of storage tanks to another storage tank through the fluid channel. 12. The method of claim 11,
The robot main body includes:
And a pair of storage tanks which intersect the virtual line connecting the pair of storage tanks is rotated about a plane intersecting line on a center axis. 12. The method of claim 11,
Wherein the pair of storage tanks is composed of an air cylinder,
Wherein the air cylinder is stored with seawater. 11. The method of claim 10,
The propulsion unit includes:
And a robot control system for a hull wall surface working robot system disposed on an upper surface of the robot body for moving the robot body to a wall surface of the hull when the posture of the robot body is changed to stand upright in a horizontal state to a vertical state by the posture changing unit . 11. The method of claim 10,
The robot includes:
A traveling unit provided at a lower portion of the robot body for allowing the robot body to travel along the wall surface of the ship; And
And a cleaning unit provided at one side of the robot body for removing foreign matter adhering to a wall surface of the hull. delete delete delete delete delete delete delete delete delete

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