KR20150034438A - Rail running robot apparatus for installing adiabatic box - Google Patents

Abstract

The present invention relates to a robot apparatus attaching an adiabatic box (15) while moving on a rail (20). The robot apparatus comprises: a lower actuator (30) installed in the rail (20) in contact with a driving unit having a rotatable arm (32) on an upper surface thereof; an upper actuator (40) installed in the arm (32) to support a suction plate (42) by having a four-axis actuator interposed therebetween; and a control means (50) moving the lower actuator (30) to a predetermined position, and attaching an adiabatic box (15) to the predetermined position with the arm (32) and the suction plate (42). Therefore, the robot apparatus can enhance productivity due to shortening an operational time, and improve the safety of an operator by being installed in a limited space such as a cargo hold during a construction process of an LNGC.

Description

Technical Field [0001] The present invention relates to a rail running robot apparatus for installing a heat insulating box,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat insulation box installation robot apparatus, and more particularly, to a rail traveling robot apparatus for installing a heat insulation box, which is required for a drying process of a ship for transporting LNG.

Typically, Liquefied Natural Gas Carrier (LNGC) has an insulation box in the cargo hold to transport natural gas at cryogenic liquid temperatures of approximately -163 ° C. In the case of installing the insulation box on the wall of the cargo hold when the LNGC is dried, it is mainly relying on the manual work of making two or three workers as one set.

Although many attempts have been made to automate the installation of the insulation box, there is a limit to increase the productivity of the work. Especially, interference with various structures in the workplace, entry into a narrow space, and so on, Korean Patent Registration No. 0965295 and Korean Utility Model Registration No. 0441414 are known as prior art documents relating to automation in the field.

The prior art document of the former includes a video photographing apparatus which photographs and transmits an image on which the heat insulating panel is installed; A remote controller for transmitting the image information and the control signal; A robot controller for processing the signal and transmitting a drive control signal; A robot for attaching the heat insulating panel by the robot control device; And a control input device for transmitting to the robot control device. Accordingly, it is expected that not only the productivity of the ship is shortened by shortening the ship construction period, but also the safety accident caused by carelessness of the operator can be prevented in advance.

The latter prior art document discloses an electric pallet truck for transporting an air balance device; An air balance device installed at the center of both ends of the outrigger to reduce the load when installing the heat insulating box; A jig frame hinged to the two-stage lift arm to support the entire jig; A brake for restricting jig rotation; And a vacuum pad frame horizontally coupled to the jig frame to rotate the heat insulating box with a vacuum pad. Therefore, productivity is expected to be improved by ensuring the safety of workers and performing continuous work.

However, according to the prior art documents described above, since it is based on a general scara type robot having a relatively large driving radius of the robot arm, interference with surrounding structures is inevitable, which results in a decrease in work productivity.

1. Korean Patent Registration No. 0965295 entitled " Automatic Adhesive Panel Attachment System "(Published on June 3, 2009) 2. Korean Utility Model Registration Bulletin No. 0441414 "Installation Device for LNG Ship's Insulation Box" (Published on 8. 8. 2008)

SUMMARY OF THE INVENTION It is an object of the present invention to overcome the above-mentioned problems in the prior art, and it is an object of the present invention to provide a heat insulation box which is installed in a narrow place such as a cargo hold in a drying process of LNGC to improve productivity by shortening working time, There is provided a rail driving robot apparatus for installation.

In order to achieve the above object, the present invention provides a robot apparatus for attaching a heat insulating box while moving a rail, the robot apparatus comprising: a lower driving body installed on the rail in contact with a traveling machine, An upper driving body installed on the arm to support the attracting plate via four football motions; And a controller for moving the lower driver to a set position and attaching the heat insulating box to the set position with the arm and the attracting plate.

In addition, according to the present invention, the arm of the semi-spherical body is rotationally moved through the operating cylinder.

According to the present invention, the attracting plate of the upper driving body is supported on the arm so as to be able to move in X-Y-Z-theta through the supporting plate and the supporting shaft.

According to the present invention, the control means comprises a controller, a position sensor for detecting a moving state of the lower driving body and the attracting plate, and a force sensor for detecting a load change acting on the arm.

In addition, according to the present invention, the lower driving body is provided with an outrigger rotatable to prevent overturning in response to a change in the center of gravity acting on the arm.

As described above, according to the present invention, in the drying process of LNGC, it is installed in a narrow place such as a cargo hold, thereby improving the productivity by shortening the working time and improving the safety of the worker.

1 is a configuration diagram showing a standby state of a robot apparatus according to the present invention;
2 is a configuration diagram showing a state after movement of the robot apparatus according to the present invention;
Fig. 3 is a configuration diagram showing a state in which the robot apparatus according to the present invention adsorbs a heat insulating box
4 and 5 are diagrams showing a state in which the robot apparatus according to the present invention is attached with a heat insulating box

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

The present invention proposes a robot apparatus for attaching the heat insulating box (15) while moving the rail (20). The cargo hold of the LNGC has a heat insulating box 15 for storing LNG in a cryogenic liquid state as a polyhedral space including a bottom surface 11 and a wall surface 12. The present invention is directed to a robot apparatus for attaching a heat insulating box (15) to a wall surface (12) of a cargo hold in a predetermined order, but is not limited thereto. The rail 20 may be temporarily installed on the bottom surface 11 and may include a reflector to assist in detecting the position of the lower driver 30. [

The present invention relates to a robot apparatus comprising a lower drive body (30) and an upper drive body (40) based on a rail (20) And avoid interference with.

In the following description, the front and rear sides refer to the direction perpendicular to the rail 20, not the traveling direction of the rail 20.

According to the present invention, a lower driving body 30 having an arm 32 rotatable on an upper surface thereof is installed on the rail 20 so as to be in contact with the traveling machine 31. The traveling unit 31 of the lower driving body 30 is brought into contact with the rail 20 and is driven to move to the set position. The traveling machine 31 also has a braking function that generates propulsive force by the servo motor and stops at a desired position without rocking. The arm 32 is installed on the upper surface of the lower driving body 30 with a hinge interposed therebetween so as to be rotated in a range of at least 90 degrees which is converted into a vertical and horizontal attitude.

According to the detailed configuration of the present invention, the arm 32 of the lower driving body 30 performs a rotary motion through the operating cylinder 34. [ The actuating cylinder 34 causes the vertical and horizontal posture of the arm 32 as a hydraulic cylinder or pneumatic cylinder. The number of the operating cylinders 34 is increased or decreased according to the weight of the heat insulating box 15. The pneumo-hydraulic pressure generating device may be incorporated in the lower driving body 30 or may be connected to the outside.

According to the present invention, the upper driving body 40 is provided on the arm 32 so as to support the attracting plate 42 via the four football motors 46. The suction plate 42 of the upper driving body 40 is provided with a plurality of suction pads 44 on its front surface and grips the heat insulating box 15 by the vacuum pressure of the vacuum pressure generator built in the lower driving body 30 . The suction plate 42 is moved in a fine motion through the four-football synchronizer 46 in the process of gripping the heat insulating box 15 and transferring it to the wall surface 12 and attaching it. The four-wheel-drive synchronizer 46 uses the respective servo motors for precise position control with respect to the heat insulating box 15.

According to the detailed configuration of the present invention, the attracting plate 42 of the upper driving body 40 is supported by the arm 32 via the supporting plate 41 and the supporting shaft 43 in XYZ-theta motion . The support plate 41 is mounted on the arm 32 so as to be capable of vertical movement (Y axis) and rotational movement (? Axis) via the support shaft 43. The attracting plate 42 is supported on the support plate 41 in the left- (X axis) and forward and backward movement (Z axis). Of course, the back and forth movement of the adsorption plate 42 is realized by moving the adsorption pad 44 to and from the support plate 41 through a separate plate on which the adsorption pad 44 is mounted. Accordingly, the attracting plate 42 can realize the four-axis motion of X-Y-Z- &thetas;, so that the heat insulating box 15 waiting at a certain position can be sequentially attached to the wall surface 12.

According to the present invention, the control means 50 moves the lower driving body 30 to the set position and controls the arm 32 and the suction plate 42 to attach the heat insulating box 15 to the set position. The control means 50 controls the position of the arm 32 of the lower driving body 30, the position of the suction plate 42 of the upper driving body 40, the emergency state of the operation process, and the like.

According to the detailed configuration of the present invention, the control means 50 includes a controller 52, a position sensor 54 for detecting the moving state of the lower driving body 30 and the attracting plate 42, And a force sensor (56) for detecting a change in load caused by the load. The controller 52 is mounted on the lower driver 30 as a microcomputer circuit including a memory, a microprocessor, and an input / output interface. The position sensor 54 uses the LDS and acquires movement position information of the lower driver 30 and the upper driver 40 in conjunction with the reflection plate of the rail 20 described above. In this case, the position sensors 54 are installed in plural so that the cross-recognition of the heat insulating boxes 15 located at the upper, lower, left, and right sides can be recognized. The force sensor 56 is installed on the arm 32 or the support shaft 43 and acquires information on a change in load during the adsorption and adhesion work. When the load rapidly changes to the normal value or less, the heat insulating box 15 of the adsorption plate 42 is dropped in the middle of the operation. If the load suddenly changes beyond the normal value, high pressure acts on the heat insulating box 15 or interference occurs on the arm 32 State.

Of course, the control means 50 may also include a sensor for detecting whether or not the heat insulating box 15 is held by suction, a camera for photographing the fine movement of the arm 32, and a communication module for exchanging information with the outside .

According to the detailed structure of the present invention, the lower driving body 30 is provided with an outrigger 35 capable of rotating to prevent overturning in response to a change in the center of gravity acting on the arm 32. Since the robot apparatus of the present invention has a design feature that conforms to a lightweight and compact design, there is a fear of overturning due to a change in center of gravity generated in the process of lifting and attaching the heat insulating box 15. The outrigger 35 is an L-shaped supporter installed on both sides of the lower driving body 30, and rotates to the opposite side where the heat insulating box 15 moves to stably maintain the center of gravity.

Of course, it is also possible to provide a counterbalance (not shown) that moves back and forth in place of the outrigger 35 or inside the lower driver 30 together with the outrigger 35.

In operation, the rails 20 are installed in front of the wall 12 as shown in Fig. 1, the robot apparatus is kept in a standby state, and a plurality of the heat insulating boxes 15 are placed in front of the work target wall surface 12, When the controller 52 of the means 50 is operated, the travel of the robot apparatus is started by the traveling device 31 of the lower drive body 30, and the position is detected by the position sensor 54, (See Fig. 2).

Next, while the arm 32 rotates forward by the operating cylinder 34 and the attracting plate 42 approaches the heat insulating box 15, the outrigger 35 rotates forward to maintain the center of gravity 3), and the arm 32 is lifted again by the operating cylinder 34, so that the suction plate 42 is pulled up by the suction plate 44. As a result, The outrigger 35 is moved backward while the heat insulating box 15 faces the wall surface 12 by the θ axis movement of the heat insulating box 42 (see FIG. 4) and the heat insulating box 15 is attached to the correct position by the fine movement of the XYZ axis So as to maintain the center of gravity (see Fig. 5).

As described above, according to the present invention, the gripping and installing process of the heat insulating box 15 is simple and the installation time is minimized, and the movement time of the work place can be minimized by running the rail 20.

On the other hand, after the set operation is completed, the rail 20 and the robot apparatus can be removed and installed in the next place, and the operation can be continued in the same manner.

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 and scope of the invention as defined by the appended claims. It is therefore intended that such variations and modifications fall within the scope of the appended claims.

11: bottom surface 12: wall surface
15: Insulation box 20: Rail
30: lower driving body 31: traveling machine
32: arm 34: working cylinder
36: Outrigger 40: Upper drive body
41: Support plate 42: Suction plate
43: support shaft 44: adsorption pad
46: 4 soccer sync 50: control means
52: controller 54: position sensor
56: force sensor

Claims (5)

A robot apparatus for attaching a heat insulating box (15) while moving a rail (20), comprising:
A lower driving body 30 installed on the rail 20 so as to be in contact with the traveling machine 31 and having an arm 32 rotatable on an upper surface thereof;
An upper driver 40 installed on the arm 32 to support the attracting plate 42 via a four-football synchronizer 46; And
And a control means (50) for moving the lower driving body (30) to a set position and controlling the attachment of the heat insulating box (15) to the setting position by the arm (32) and the suction plate (42) Rail moving robot device for installing insulation box. The method according to claim 1,
Characterized in that the arm (32) of the lower driver (30) carries out a rotary motion via the operating cylinder (34). The method according to claim 1,
Characterized in that the suction plate (42) of the upper drive body (40) is supported by the arm (32) so as to be movable in the XYZ-theta direction via the support plate (41) and the support shaft (43) . The method according to claim 1,
The control means 50 includes a controller 52, a position sensor 54 for detecting the moving state of the lower actuator 30 and the attracting plate 42, a force detecting means for detecting a load change acting on the arm 32, And a sensor (56). The method according to claim 1,
Wherein the lower driving body (30) is provided with an outrigger (35) capable of rotating to prevent overturning in response to a change in the center of gravity acting on the arm (32).

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