KR20120056354A - Robot for cleaning of ship hull and robot remote control apparatus - Google Patents

Abstract

PURPOSE: A cleaning robot for the lower part of a ship and a remote control device thereof are provided to prevent interference by adjusting a connection cable which connects a remote controller and the cleaning robot. CONSTITUTION: A cleaning robot for the lower part of a ship comprises a bogie(200) and a robot hand(100). Magnetic wheels having magnets are installed in both sides of the frame of the bogie. When the bogie travels on the wall surface of a ship body, the robot hand cleans the wall surface of the ship body using a cleaning tool. The robot hand comprises a rotary brush and a brush support(120). The rotary brush brushes the wall surface of the ship body. The brush support has an articulated link for supporting the rotary brush.

Description

ROBOT FOR CLEANING OF SHIP HULL AND ROBOT REMOTE CONTROL APPARATUS}

A cleaning robot installed on a mobile truck driving a magnetic wheel to freely travel a hull wall surface, and relates to a ship bottom cleaning robot and a remote control device for the robot to clean the adhesive attached to the hull wall surface.

Vessels can be attached to the surface of marine life due to environmental factors that operate at sea, and submerged ship bottoms provide good environmental conditions for the adhesion and growth of marine life. It not only slows down the navigation, but also increases unnecessary fuel consumption.

Conventionally, a cleaning operation in which a ship is moved to an on-shore dock and a worker directly sprays water with a high pressure hose to remove the adhesive on the hull wall has been generally used. This requires a preparation procedure to move the vessel to be cleaned to the dock, which requires a long cleaning time and requires a large number of personnel.

Divers can get into the water without cleaning the ship and clean the bottom of the ship with the cleaning equipment, but even divers skilled in the underwater environment will take a long time to clean a wide range of hulls, and attachments falling from the hull will clean the wide range of ship bottoms. It takes a long time and the clock is difficult to secure, which increases the difficulty of cleaning.

In the harsh environment where the worker cleans the ship hull, it is difficult to remove the adhesive and the work force is required. The application of a mixture of paints is used, but it is prohibited by international organizations as it causes other problems that can contaminate sea water and have a detrimental effect on other marine life, destroying aquatic ecosystems. Also, if the toxicity decreases after a certain period of time, paint should be reapplied after cleaning.

In consideration of such various problems, a technique has been disclosed in which a cleaning robot removes sediment while moving a submerged hull wall.

Underwater robot for bottom cleaning and inspection is a device that generates propulsion force and it is known to move along the hull wall and clean it using a brush fixed to the underwater robot. It is difficult to efficiently clean the hull bottom with large curvature due to the large size of the equipment, and it requires a lot of sensors to move the hull wall surface stably with a propulsion device.

Korean Utility Model Model No. 20-0438708 discloses a method of moving a hull wall surface using a plurality of wheels mounted on the left and right sides of the body and having permanent magnets mounted on the lower body of the body. This work carrier is installed on the front or back plate of the body to clean the working surface by brushing means is made in the form of a roll brush can remove the foreign matter adhering to the surface with a rotating brush, the adhesive on the hull wall Not suitable for removing it.

The existing technique described above is equipped with a brush as a cleaning tool, but the former prior art can adjust the height of the brush with a hydraulic cylinder so as not to increase the adhesion of the brush, but can not change the brush position does not extend the cleaning range. The latter prior art also does not disclose a method of changing the cleaning range by changing the position of the brush.

Considering that the cleaning robot for cleaning the hull wall is manufactured for the purpose of cleaning a wide range without the help of the operator, the cleaning position is changed stably to the hull wall underwater while changing the position of the brush during the cleaning operation. There is a need for a technology that enables the implementation of the system.

In addition, when controlling the operation of the cleaning robot by remote control, the length of the connection cable between the cleaning robot and the remote controller should be adjusted appropriately. This is because the length of the connection cable is long, so it is necessary to adjust the length of the connection cable, such as burdening the running of the cleaning robot.

One aspect of the present invention is to change the position of the rotary brush mounted on the robot hand while driving stably attached to the hull wall surface using a magnetic force to quickly clean the hull submerged in the water.

Another aspect of the present invention is to remotely control the operation of the cleaning robot in the remote controller located on the ship and adjust the length of the connection cable connecting the remote control and the cleaning robot to prevent the occurrence of a failure due to the interference of the cleaning robot and the connection cable. To prevent.

To this end, the ship bottom cleaning robot according to the embodiment includes: a moving trolley for installing magnet wheels with magnets on both sides of the frame so as to be attached to the hull wall and to drive the wheels by motor power; And a robot hand for cleaning the hull wall surface by using a cleaning tool driven by the moving cart according to a control command when the moving cart drives the hull wall surface, wherein the mobile bogie is fixed to one side of the frame and is attached to the hull wall surface. And a square magnet block accommodating a square magnet installed at a predetermined distance from the other side, wherein the attachment force of the movable trolley to the hull wall surface is a magnetic force acting between the square magnet of the square magnet block and the hull wall surface. Determined by the sum of the magnetic forces acting between the magnet of the wheel and the hull wall surface, the robot hand has a brush support having a rotary brush for removing adhesive on the hull wall surface and a articulated link supporting the rotary brush. And drive the articulated link to change the cleaning range of the rotating brush Key includes a robot control unit for controlling the motor linked.

The rotating brush includes a brush holder having a plurality of brush teeth fixed therein and a brush motor rotating the brush holder in a forward or reverse direction, and the robot controller measures a force feedback sensor for measuring an applied reaction force of the articulated link. Control the brush motor according to the value.

When the measured value of the force feedback sensor is larger than a predetermined value, the robot controller stops or rotates the brush holder rotating in either direction or the other direction.

The brush support includes a fixed link and a plurality of movable links coupled to the fixed link, wherein the link motor drives the plurality of movable links to change the position of the rotary brush coupled to at least one of the plurality of movable links. Drive the link.

The cleaning robot cleans the hull wall by changing a driving path according to a control command of a remote controller installed on the ship or outside the ship.

To this end, the control device of the ship bottom cleaning robot according to the embodiment includes a moving trolley for traveling the hull wall surface using magnetic force and a robot hand installed on the mobile trolley to clean the hull wall surface, and the hull wall surface is cleaned. A cleaning robot having an underwater camera for photographing the state; A connection cable including a power supply line for supplying power to the cleaning robot, a control signal transmission line for transmitting a control command, and an image signal transmission line for transmitting an image captured by the underwater camera; A winch having a rotating drum winding the connecting cable and a drum motor driving the rotating drum in accordance with a winch control command; Outputs an image of the cleaning state of the hull wall surface, controls the movement of the moving trolley and the robot hand according to a user's operation command, and adjusts the length of the connection cable wound on the winch according to the movement of the moving trolley It includes; a remote controller for outputting the winch control command.

The robot hand includes a brush support having a rotating brush and an articulated link supporting the rotating brush, and the cleaning robot includes a robot control unit controlling a link motor of the brush support under control of the remote controller. The link motor changes the position of the movable link constituting the articulated link.

The remote controller includes a recording unit for recording an image signal photographing the cleaning state.

The robot control unit changes the position of the movable link in a direction to attenuate the reaction force of the movable link.

As described above, the ship bottom cleaning robot and the remote control device of the robot according to the embodiment can quickly remove the adhesive while the robot hand mounted on the moving trolley stably travels the hull wall.

In addition, the ship bottom cleaning robot according to the embodiment and the remote control device of the robot can adjust the length of the connection cable when the remote control of the operation of the cleaning robot using a remote controller located on the ship can operate the cleaning robot normally. .

1 is a perspective view of a ship bottom cleaning robot according to an embodiment of the present invention.
FIG. 2 is a bottom view of FIG. 1.
3 is a side view of FIG. 1.
4 is a schematic configuration diagram of a remote control apparatus for a ship bottom cleaning robot according to an embodiment of the present invention.
5 is a view for explaining the winch of FIG.
6 is a block diagram of a control device of the cleaning robot for cleaning the vessel bottom according to an embodiment of the present invention.
7A and 7B are views for explaining the operation of the robot hand for cleaning the hull wall surface according to the embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 3, the ship bottom cleaning robot 10 (hereinafter referred to as a cleaning robot) according to the present invention includes a robot hand 100 for cleaning using a rotating brush 110 that is a cleaning tool. It may include a moving cart 200 for traveling the hull wall.

The mobile trolley 200 includes a pair of magnet wheels 210, suspension 220, a coupling 230, a square magnet block 240, and a urethane wheel 250 installed on both sides of the frame 201. Wheel motors 260 and 261 and a chain gear 270 for driving the magnet wheels 210 may be included.

Since the detailed configuration of the mobile truck 200 is described in Korean Application No. 10-2008-89815, an invention filed by one of the co-applicants of the present invention, overlapping portions will be briefly described.

Frame 210 is made of a substantially hexagonal in appearance can be equipped with a device for providing motor power to the robot hand 100 and the magnet wheel (210).

A pair of magnet wheels 210 are installed at both lower sides of the frame 210, and urethane wheels 250 are installed at the front and rear of the bottom of the frame 210.

The magnet wheel 210 has a structure in which cylindrical magnets are embedded in a disc of nonferrous metal, and discs of ferrous metal are tightly coupled to both sides of the cylindrical magnet, and discs of nonferrous metal are coupled to both outermost sides thereof. The outer circumferential surface of the outermost disc is coated with urethane to increase traction when attached to the hull wall to prevent slippage.

The urethane wheel 250 is coated with urethane on the outer circumferential surface, and the moving trolley 200 is provided to improve steering ability when moving forward or backward.

The wheel motors 260 and 261 provided on the upper portion of the frame 201 may individually drive the pair of magnet wheels 210, and selectively rotate the magnet wheels 210 on both sides when the moving cart 200 rotates. To transmit power.

The motor power is transmitted through a chain gear 270 connected between the wheel motors 260 and 261 and the magnet wheel 210. The coupling 230 decelerates the motor power transmitted through the chain gear 270 at an appropriate speed to drive the magnet wheel 210.

When the mobile truck 200 running in the state of being attached to the hull wall depends only on the magnet wheels 210, a lack of adhesion may occur, so that a plurality of square magnet blocks are installed at a lower distance from the bottom surface of the frame 201. 240 is provided.

The square magnet block 240 is made of a structure that doubles the magnetic force by wrapping the rectangular magnet of the rectangular parallelepiped accommodated therein with an aluminum block and blocking the upper surface with ferrous metal. In addition, the square magnet block 240 may include an adjustment screw for adjusting the attachment force by adjusting the separation distance with the bottom surface.

As such, the attachment force of the moving trolley 200 is determined by the sum of the magnetic force acting between the square magnet of the square magnet block 240 and the hull wall and the magnetic force acting between the cylindrical magnet of the magnetic wheel 210 and the hull wall. .

The robot hand 100 is installed at the head of the frame 201 and cleans the hull wall surface according to the movement of the moving trolley 200.

The robot hand 100 may include a rotating brush 110 that rotates at high speed and a brush support 120 that supports the rotating brush 110.

Rotating brush 110 is arranged in a circle in the brush motor 111 and the brush holder 112 and the brush holder 112 that is integrally coupled to the brush motor 111 to rotate in the forward or reverse direction integrally coupled to the brush motor 111 And include a plurality of brush teeth 112 that are fixed and made of a rigid material. Brush teeth 113 are slightly bent and the ends rotate close to the hull wall surface.

Brush support 120 may include a link joint (128 ~ 132) for coupling the link joints (211 ~ 125) and the link motor 126, 127 and the links one side is fixed to the frame 201. have.

The articulated link is composed of a fixed link 121 and four movable links 121 to 125 that can be adjusted in position. In the embodiment, the articulated link is implemented as a 5 articulated link, but the number of joints can be added or subtracted as needed.

The fixing link 121 is made of a plate shape is fixed to one side of the frame 201.

Link motors 126 and 127 are installed in the fixed link 121 and adjust the positions of the two movable links 122 and 123 according to the control command. The two movable links 122 and 123 are installed in the fixed link 121 by the link couplers 128 and 129, respectively, and are pivoted by the link motors 126 and 127.

The link coupler 130 couples the movable link 122 driven by the link motor 126 and the movable link 124 at an end thereof, and the link coupler 131 drives the movable link 122 driven by the link motor 127. 123 and the end of the movable link 125, the link coupler 132 supports the brush motor 111 and at the same time to engage the end of the movable link (124, 125).

The positions of the two movable links 122 and 123 may be changed by driving the link motors 126 and 127. That is, when the two movable links 122 and 123 are pivoted so that a large gap is opened between the two movable links, the rotary brush 110 approaches the fixed link 121, and when the two movable links become smaller, the rotary brush 110 opens. Away from the fixed link 121. In addition, if one of the two movable links 122 and 123 is fixed to one side of the movable link and the position of the other movable link is changed, the positions of the two movable links 124 and 125 holding the rotary brush 110 are changed. I can adjust it. Accordingly, the position of the rotating brush 110 during the cleaning operation may be changed in the left and right or front and rear directions.

The two movable links 122 and 123 are made in parallel to increase rigidity. Since the support state of the rotary brush 110 may be unstable due to vibration during the cleaning operation, the adhesion between the rotary brush 110 and the bottom surface is not deteriorated and is to be stably cleaned.

The cleaning robot 10 may independently clean the hull wall using a work program stored in the robot control unit 11 controlling the cleaning robot 10. However, the cleaning state made by the cleaning robot 10 is not cleaned while checking the cleaning robot 10 itself. In consideration of this point, the underwater camera 140 may be installed in the fixed link 121, and an operator located on the ship may remotely control the cleaning robot 10 by using the image captured by the underwater camera 140. . This operation is described.

As shown in Figure 4, the remote control device for a ship bottom cleaning robot according to an embodiment of the present invention is a winch 20 and a remote controller (located on the ship 1 to remotely control the cleaning robot 10) 30) and a connection cable 40 for connecting between the cleaning robot 10 and the remote controller 30.

As shown in FIG. 5, the winch 20 is configured to wind or unwind the connecting cable 40 by rotating the rotating drum 23 and the rotating drum 23 forward or reversely provided in the main body 22. And a drum motor 21.

The drum motor 21 is driven according to the winch control command of the remote controller 30, and a reducer motor may be used to pull or release the connection cable 40 at a constant speed.

The cleaning robot 10 connected to the connection cable 40 is attached to the hull wall underwater submerged by using the magnetic force provided by the magnet wheel 210 and the square magnet block 240.

The connection cable 40 includes a power supply line for supplying power to the cleaning robot 10, a control signal transmission line for transmitting a control command from the remote controller 30, and an image signal transmission line for transmitting an image captured by the underwater camera. can do.

Figure 6 is a block diagram of a remote control device for a ship bottom cleaning robot according to an embodiment of the present invention.

The cleaning robot 10 includes a robot controller 11 for controlling the overall operation of the cleaning operation, a wheel motor driver 12 for driving the wheel motors 260 and 261, and a link motor 260 and 261. It includes a link motor driver 13 for driving, and a brush motor driver 16 for driving the brush motor 111.

The robot controller 11 communicates with the remote controller 31 of the remote controller 30 connected by the connection cable 40.

The remote control unit 31 transmits a control command for controlling the cleaning robot 10 to the robot control unit 11 according to an operator's input command input through an operation unit 32 such as a keyboard, a mouse, or a joystick.

The robot controller 11 controls the wheel motor driver 12 to control the traveling operation of the mobile truck 200 according to the control command of the remote controller 31. The robot controller 11 controls the link motor driver 13 or the brush motor driver 16 to control the cleaning operation of the robot hand 110.

Reaction force applied to the movable links 122 to 125 is generated when the hull wall is cleaned using the rotary brush 110. A force feedback sensor 15 is installed on the movable links 122 to 125 for the purpose of reducing such reaction force.

During the cleaning operation with the rotary brush 110, the force feedback sensor 15 measures the reaction force applied to the movable links 122 to 125, and provides the measured value to the robot controller 11.

The robot control unit 11 adjusts the position with respect to the movable links 122 to 125 in a direction to attenuate the reaction force according to the measured value provided from the force feedback sensors 15 installed on the movable links 122 to 125.

The video signal photographed by the underwater camera 140 is transferred to the remote controller 30 through the connection cable 40, and the remote controller 31 outputs the image through the monitor 33 to allow the operator to perform the cleaning. To check. In this case, when recording is set through the operation unit 32, the remote control unit 31 may perform an operation of recording the captured image signal to the recording unit 34.

The operator checks the cleaning state on the monitor 33 and inputs an input command for adjusting the length of the connecting cable 40 to the operation unit 32, and the remote control unit 31 sends a winch control command to the drum motor according to the input command. Is applied to (21). Then, the drum motor 21 may be rotated forward or reverse to wind or unwind the connecting cable 40 to the rotating drum 23 to adjust the length of the connecting cable 40 connected to the cleaning robot 10.

As shown in FIG. 7A, the cleaning robot 10 adjusts the position of the rotating brush 110 of the robot hand 100 in the front-rear direction while driving the moving trolley 200 under the control of the remote controller 20. The cleaning operation may be performed by performing the cleaning operation or by adjusting the rotation brush 110 in the left and right directions as illustrated in FIG. 7B. Since the work area can be changed by adjusting the position of the rotary brush 110, a wide cleaning range can be quickly cleaned, and the traveling distance of the moving cart can be shortened.

1: Ship 10: Cleaning Robot
11: robot control unit 12: wheel motor drive unit
13 link motor drive unit 16 brush motor drive unit
20: winch 21: drum motor
22: main body 23: rotating drum
30: remote controller 31: remote control
32: control panel 33: monitor
34: recording unit 40: connection cable
100: robot hand 110: brush moving part
111: brush motor 112: brush holder
113: brush flesh 120: brush support
121: fixed link 122-125: movable link
126, 127: link motor 128 ~ 132: link coupler
140: underwater camera 200: moving cart
201: support frame 210: magnet wheel
220: suspension 230: coupling
240: square magnet block 250: urethane wheel
260, 261: wheel motor 270: chain gear

Claims (9)

A mobile trolley for installing magnet wheels with magnets on both sides of the frame so as to be attached to the hull wall and to drive the wheels;
And a robot hand for cleaning the hull wall surface by using a cleaning tool which is driven according to a control command when the moving cart drives the hull wall surface.
The moving bogie includes a square magnet block for receiving a square magnet having one side fixed to the frame and the other side installed at a predetermined distance from the other side of the hull wall.
The attachment force of the moving trolley to the hull wall is determined by the sum of the magnetic force acting between the square magnet of the square magnet block and the hull wall and the magnetic force acting between the magnet of the magnet wheel and the hull wall,
The robot hand includes a brush support having a rotating brush for removing adhesive on the hull wall and an articulated link supporting the rotating brush,
And a robot controller for controlling a link motor for driving the articulated link to change the cleaning range of the rotary brush. The method of claim 1,
The rotating brush includes a brush holder to which a plurality of brush flesh are fixed and a brush motor for rotating the brush holder in a forward or reverse direction,
And the robot controller controls the brush motor according to a measured value of a force feedback sensor for measuring the reaction force applied to the articulated link. The method of claim 2,
And the robot controller stops the brush holder rotating in one direction or rotates in the other direction when the measured value of the force feedback sensor is greater than a predetermined value. The method of claim 1,
The brush support includes a stationary link and a plurality of movable links coupled to the stationary link,
And the link motor drives the plurality of movable links to change the position of the rotary brush coupled to at least one of the plurality of movable links. The method of claim 1,
And the cleaning robot cleans the hull wall by changing a driving path according to a control command of a remote controller installed on a ship or outside of the ship. A cleaning robot provided with a moving trolley for traveling the hull wall using magnetic force, a robot hand installed on the moving trolley for cleaning the hull wall, and an underwater camera for photographing the cleaning state of the hull wall;
A connection cable including a power supply line for supplying power to the cleaning robot, a control signal transmission line for transmitting a control command, and an image signal transmission line for transmitting an image captured by the underwater camera;
A winch having a rotating drum winding the connecting cable and a drum motor driving the rotating drum in accordance with a winch control command;
Outputs an image of the cleaning state of the hull wall surface, controls the movement of the moving trolley and the robot hand according to a user's operation command, and adjusts the length of the connection cable wound on the winch according to the movement of the moving trolley And a remote controller for outputting a winch control command. The method of claim 6,
The robot hand includes a brush support having a rotating brush and a articulated link supporting the rotating brush,
The cleaning robot includes a robot controller for controlling the link motor of the brush support unit under the control of the remote controller,
The link motor is a remote control device of the ship bottom cleaning robot for changing the position of the movable link constituting the articulated link. The method of claim 6,
The remote controller is a remote control device for a ship bottom cleaning robot including a recording unit for recording an image signal photographing the cleaning state. The method of claim 7, wherein
The robot control unit is a remote control device of the ship bottom cleaning robot for changing the position of the movable link in the direction of reducing the reaction force of the movable link.

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