KR20170111967A - Parallel robot apparatus - Google Patents

Abstract

According to the present invention, four vertically installed frames (R) are provided upright on each corner of a square or rectangular work area (R), and on the inside facing the center of the work area (R) 110); A drive belt 121 which is inserted and rotated between two rollers 131 and 132 spaced apart from the upper and lower portions of the vertical frames 110 and a drive motor 122 for providing a rotational force to the drive belt 121 A driving unit 120 including the driving unit 120; A slider 141 which moves up and down along the rail 111 in a state of being fastened to one side of the drive belt 121, an effector 142 horizontally disposed in the work area R, A moving part 140 including a link frame 143 linearly connected between the effector 142 and the moving part 140; And a controller for individually driving and controlling the respective driving motors 122 according to a user input signal to move the effector 142 in a horizontal state in the working area R. [

Description

PARALLEL ROBOT APPARATUS [0002]

[0001] The present invention relates to a parallel robot apparatus, and more particularly, to a parallel robot apparatus used for parallelly moving a working device such as a gripper, a vacuum pick-up machine, and a welding machine in a certain work space.

Parallel robotic devices are used in automated production lines where repetitive tasks are generally performed. Fig. 1 shows a configuration of a conventional parallel robot apparatus.

Referring to FIG. 1, a conventional parallel robot apparatus 10 includes a base 11 supported by a vertical frame installed upright on each corner of a triangular working area and disposed horizontally at a predetermined height, And three pairs of robot arms connected to each other to receive the rotational force of the driving motor 12 and adjust the angle of the folding.

Each of the robot arms has a first arm 30 connected to the base 11 and angularly adjusted by the drive motor 12 and a second arm 30 connected to the end of the first arm 30 by the universal link 20, And the end portion is composed of a second arm (40) coupled to the periphery of the effector.

In order to move the effector in parallel in the work area, the drive motors 12 are individually driven and controlled to synchronize the folding angles of the robot arms so that the effector is moved in the x, y, and z axes I could move it.

However, since the conventional parallel robot apparatus needs to adjust the folding angle of each robot arm having a joint structure for movement control, it is necessary to use a driving motor having a high output. In order to precisely control the movement of the joint, There is a problem that the manufacturing cost and the installation cost are increased and the driving control becomes complicated.

Furthermore, since the three vertical frames supporting the load of the apparatus as shown in the figure are erected in a triangular structure, when the apparatus is installed so as to work the articles to be conveyed on the conveyor, if the conveyor is arranged through the two vertical frames, It is necessary to enlarge the interval between the vertical frames in order to avoid interference. Therefore, the size of the apparatus must be excessively large. Nevertheless, there is a narrow problem in the working area.

Japanese Patent Application Laid-Open No. 10-2015-0077699 (Aug. 20, 2018), Universal Link for Delta Robot

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a high- And it is an object of the present invention to provide a paralel robot apparatus having a structure that can greatly reduce manufacturing cost and installation cost, and can secure a relatively wide work area without restricting the arrangement of the conveyor.

In order to achieve the above object, a parallel robot apparatus according to the present invention is provided with a rectangular or rectangular rectangular work area R, which is erected vertically for each corner, and on the inner side toward the center of the work area R, Four vertical frames 110 each of which is formed with a plurality of vertical frames 111; A drive belt 121 which is inserted and rotated between two rollers 131 and 132 spaced apart from the upper and lower portions of the vertical frames 110 and a drive motor 122 for providing a rotational force to the drive belt 121 A driving unit 120 including the driving unit 120; A slider 141 which moves up and down along the rail 111 in a state of being fastened to one side of the drive belt 121, an effector 142 horizontally disposed in the work area R, A moving part 140 including a link frame 143 linearly connected between the effector 142 and the moving part 140; And a controller for individually driving and controlling the respective driving motors 122 according to a user input signal to move the effector 142 in a horizontal state in the working area R. [

Spherical slider connecting balls 144 projecting sideways are disposed on both sides of the slider 141. Spherical shaped slider connecting balls 144 are formed on the sides of the slider 141, And the moving unit 140 includes two link frames 143 for each of the vertical frames 110. The link frames 143 are paired with the respective sides of the effector 142 and the respective sliders 141, And each link frame 143 is formed with rolling grooves 144a and 144b at both ends thereof so that one rolling groove 144a is rotatably connected to the slider connecting ball 144 and the other rolling groove 144b may be rotatably connected to the effect connecting ball 145. [

The slider 141 is disposed near the initial driving position of the predetermined slider 141 on the inner surface of the vertical frame 110 and senses the slider 141 moved to the initial driving position, Wherein the control unit receives an encoder value of each driving motor 122 from the driving unit 120 and calculates a moving distance of each slider 141, And each driving motor 122 can be individually controlled to rotate so that each slider 141 moves to a set position based on the calculated lift distance value.

The initial driving position of the slider 141 is the upper end of the rail 111 formed on the inner surface of the vertical frame 110. When the sensing signal is inputted from the sensor unit 170, It is determined that the slider 141 has moved to the initial driving position and at the same time the rotation of the driving motor 122 is stopped to prevent the slider 141 from separating from the rail 111. [

The apparatus may further include a tension roller 160 disposed on an inner surface of the vertical frame 110 to rotate and rotate one side of the driving belt 121 in a lateral direction.

The driving unit 120 includes a driving roller 131 and a driven roller 132 disposed vertically on the vertical frame 110 and a driven roller 132 rotatably supporting the driven roller 132 with a bearing A guide frame 135 which is fixed to the vertical frame 110 and supports the side of the vertical block 133 to guide the vertical movement of the vertical block 110; A fixing frame 136 fixed to the vertical frame 110 and formed with a through hole 137 at a position corresponding to the screw hole 134 and a fixing frame 136 passing through the through hole 137, And an adjusting screw 139 which is formed at the periphery thereof with a male thread to engage with the female screw thread to elevate the lifting block 133 in the direction of rotation, .

A first rotating frame 181 horizontally disposed on the lower portion of the effector 142 and rotating about a vertical axis line; and a second rotating frame 181 fixed to one side of the effector 142, A second rotating frame 183 disposed upright on one side of the first rotating frame 181 and rotating around a horizontal axis, and a second rotating frame 183 disposed on the other side of the first rotating frame 181, A second motor 184 which is fixed to one side of the second rotating frame 181 and provides a rotating force necessary for rotating the second rotating frame 183; (180) including a work machine (185) for performing an operation set according to the operation instruction.

According to the parallel processing apparatus of the present invention,

First, by vertically adjusting the vertical angle of the link frame 143 connected to the effector 142 by moving the slider 141 disposed on each vertical frame 110 by rotating the drive belt 121, 142 can be freely moved in parallel to the x-, y-, and z-axes, the effector 142 can be moved freely without using a high-output driving motor or precision reducer, compared with the prior art in which the joints of the robot arm are folded. So that the structure of the apparatus can be simplified and the control can be simplified so that the manufacturing cost and the installation cost can be greatly reduced.

Second, since the vertical frame 110 has a square structure in which four vertical frames 110 are erected at each corner of the rectangular work area R, the conveyor 10 has a rectangular structure, It can be easily disposed without interference or restriction in the form of penetrating between the vertical frames 110 and it is possible to secure a work area R that is relatively larger than the scale of the apparatus.

The sensor unit 170 is disposed close to the initial driving position of the predetermined slider 141 on the inner surface of the vertical frame 110 to sense the slider 141 moved to the initial driving position, The control unit receives the encoder value of the rotation of the drive motor 122 and calculates the lift distance of each slider 141. Based on the encoder value and the calculated lift distance value, So that the effector 142, which moves in parallel in a horizontal state, can be adjusted more precisely without an expensive high-speed decelerator.

Fourthly, when the initial driving position of the slider 141 is set to the upper position of the rail 111 formed on the inner surface of the vertical frame 110, when the sensing signal is inputted from the sensor unit 170, It is determined that the slider 141 has moved to the initial driving position and at the same time the rotation of the driving motor 122 is stopped to prevent the slider 141 from separating from the rail 111 without a stopper that generates noises or vibrations .

Fifthly, on the inner side surface of the vertical frame 110, the tension roller 160 is disposed to rotate the one side of the driving belt 121 to move the slider 141 in the lateral direction. Thus, the driving belt 121 is loosened It is possible to prevent the belt from being unintentionally separated from the driving roller 131 and the driven roller 132 and to minimize the vibration of the rotating driving belt 121. [

Sixth, since the driven roller 132 supporting one side of the driving belt 121 is moved up and down in a screw adjusting manner to adjust the distance between the driven roller 132 and the driving roller 131 disposed opposite to the driven roller 132, The tension of the drive belt 121 can be finely adjusted and the tension adjustment method can be simplified.

Seventhly, in the case of the workpiece tooth 180 mounted on the effector 142, the workpiece 180 rotates about the vertical axis by the rotational force of the first motor 182, rotates about the horizontal axis by the rotational force of the second motor 184, It is possible to direct the working machine 185 mounted on the work machine to a required working direction, thereby providing various conditions for performing various operations.

1 is a perspective view showing a configuration of a conventional parallel robot apparatus,
2 is a perspective view illustrating a configuration of a parallel processing apparatus according to a preferred embodiment of the present invention.
FIG. 3 is a side view showing a main structure of a vertical frame according to a preferred embodiment of the present invention,
4 is a plan view showing a configuration of a moving unit according to a preferred embodiment of the present invention,
FIG. 5 is a schematic view showing a state in which a parallel robot apparatus according to a preferred embodiment of the present invention is installed with various square structures around a conveyor,
6 is a schematic view showing the construction of a workpiece tooth according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately The present invention should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

The parallel robot apparatus 100 according to the preferred embodiment of the present invention can move the effector 142 provided with the workpiece 180 at a high speed and in parallel without using a high output driving motor or a precision speed reducer, A robot apparatus having a structure in which control is simple and manufacturing cost and installation cost can be greatly reduced and a relatively large work area can be ensured without restricting the arrangement of the conveyor 10, 3, includes four vertical frames 110, a driving unit 120, a moving unit 140, and a control unit.

First, the four vertical frames 110 are frame structures forming a frame of the parallel robot apparatus 100, and are installed upright on each corner of a square or rectangular work area R, And a rail 111 extending vertically is formed on the inner side facing the center.

The top plate 114 is horizontally disposed on the upper portion of the vertical frame 110 and the upper plate 114 is coupled to the upper portion of the vertical frame 110. The base plate 112 is horizontally disposed on the lower portion, The vertical frame 110 can be directly fixed to the floor without the base plate 112 when the bottom surface of the installation place is rigid, Can be omitted.

In addition, as shown in the drawing, the rail 111 is vertically extended vertically and spaced apart from each other at a predetermined distance in the lateral direction for each vertical frame 110, so that the slider 141 of the moving part 140 can be stably And a support leg 113 for disposing the parallel robot apparatus 100 at a predetermined height may be disposed below the base plate 112.

The driving unit 120 is a driving unit that provides a driving force necessary for the parallel robot apparatus 100 to operate and a driving unit that is disposed between the driving roller 131 and the driven roller 132, And a driving motor 122 for providing a rotational force to the driving belt 121. The driving motor 121 may be a motor,

Here, a chain or wire may be used as the power transmission means instead of the drive belt 121, but it is preferable to use a belt having a toothed groove formed on its inner side for high-speed rotation and precise control.

3, the driving unit 120 includes a rotating plate 138a having a predetermined diameter and being axially connected to the driving roller 131 in a concentric manner, the driving motor 122 and the rotating plate 138a, And a speed reduction ratio of the motor can be adjusted as desired by adjusting the diameter of the rotation plate 138b.

In addition, on the inner side surface of the vertical frame 110, tension rollers 160 and 161 for rotating the one side of the drive belt 121 for moving the slider 141 to the side are disposed. Thus, the drive belt 121 is loose It is possible to prevent the belt from being unintentionally separated from the driving roller 131 and the driven roller 132 and to minimize the vibration of the rotating driving belt 121. [

As shown in the enlarged view of FIG. 3, the driving unit 120 includes a lifting block (not shown) having a screw hole 134 formed at one side thereof to rotatably support the driven roller 132 with bearings, A guide frame 135 fixed to the vertical frame 110 and supporting a side of the lifting block 133 to guide the lifting movement of the lifting block 133; A fixing frame 136 through which a through hole 137 is formed at a position corresponding to the through hole 134 and an end portion through which the through hole 137 is inserted into the through hole 134, And an adjusting screw 139 for moving the lifting block 133 up and down according to the rotating direction.

The driven roller 132 is supported by the tension adjusting unit 130 so that the driven roller 132 is rotated and supported by the drive roller 131 So that the tension of the driving belt 121 can be finely adjusted and the tension adjusting method can be simplified.

The moving unit 140 is configured to move the lifting and lowering operation of the slider 141 that supports the workpiece teeth 180 and ascends and descends according to the rotational force of each driving motor 122 to an operation for moving the effector 142 in parallel A slider 141 that moves up and down along the rail 111 while being coupled to one side of the drive belt 121; an effector 142 horizontally disposed in the work area R; And a link frame 143 that is connected to the effector 142 by a straight line.

4, a spherical slider connection ball 144 projecting sideways is disposed on both sides of the slider 141, and the effector 142 is provided with a pair of slider- A plurality of link frames 143 are formed for each of the vertical frames 110 so as to form a pair of the effector linking balls 145 Each link frame 143 is formed with rolling grooves 144a and 144b at both ends thereof so that one rolling groove 144a is rotatable with respect to the slider connecting ball 144 And the rolling groove 144b of the other end is rotatably connected to the effect connecting ball 145 to obtain a degree of rotational freedom.

The control unit controls the drive motors 122 individually in accordance with a user input signal of an unillustrated operation unit. The control unit moves the effector 142 in parallel to the work area R in a horizontal state.

Meanwhile, the initial driving position of the slider 141 can be sensed through the sensor unit 170 according to the preferred embodiment of the present invention, and rotation control of each driving motor 122 can be performed using the sensor.

For this, the sensor unit 170 is disposed at an initial driving position of the predetermined slider 141 on the inner surface of the vertical frame 110, detects the slider 141 moved to the initial driving position, And a sensor unit (170) for outputting a signal,

The control unit receives the encoder value of each driving motor 122 from the driving unit 120 and calculates the moving distance of each slider 141. The encoder value and the calculated moving distance value The respective drive motors 122 can be individually controlled to rotate so that each slider 141 moves to a set position. Therefore, it is possible to more precisely adjust the position of the effector 142 that moves in parallel in a horizontal state without an expensive high-speed decelerator.

In addition, the initial driving position of the slider 141 is the upper end position of the rail 111 formed on the inner side of the vertical frame 110. When the sensing signal is inputted from the sensor unit 170, It is determined that the slider 141 has moved to the initial drive position and at the same time the rotation of the drive motor 122 is stopped so that the slider 141 can be prevented from coming off the rail 111 without a stopper structure that generates noises or vibrations .

The sensor unit 170 may detect various movements of the slider 141 by using various sensing methods such as infrared rays, ultrasound, and optical sensors. The sensor unit 170 may be disposed on one side of the vertical frame 110, Or sensing the sensing element 146 disposed on one side of the slider 141 as shown in FIG.

The parallel robot apparatus 100 according to the preferred embodiment of the present invention may further include a workpiece 180 that is installed to be able to direct the working machine 185 installed in the effector 142 in various directions .

The workpiece holder 180 includes a first rotating frame 181 horizontally disposed on the lower side of the effector 142 and rotating about a vertical axis line and a second rotating frame 181 fixedly installed on one side of the effector 142, A first motor 182 for providing a rotational force necessary for the frame 181 to rotate; a second rotating frame 183 disposed upright on one side of the first rotating frame 181 and rotating about a horizontal axis; A second motor 184 fixed to one side of the first rotating frame 181 and providing a rotational force necessary for rotating the second rotating frame 183; And a work machine 185 for performing the set operation according to the control signal of the control unit.

Here, the work machine 185 may be various devices according to the work contents of the production line in which the parallel robot apparatus 100 according to the preferred embodiment of the present invention is installed, such as a gripper, a vacuum pick-up machine, and a welder.

The workpiece 180 mounted on the effector 142 rotates about the vertical axis by the rotational force of the first motor 182 and rotates around the horizontal axis by the rotational force of the second motor 184 It is possible to direct the working machine 185 mounted on one side to a required working direction, thereby providing a condition for performing various operations.

The slider 141 disposed on each of the vertical frames 110 is moved up and down by rotating the drive belt 121 by the structure and function of the parallel block robot 100 according to the preferred embodiment of the present invention, Since the effector 142 can be moved in parallel by adjusting the vertical angle of the link frame 143 connected to the effector 142 in a straight line, the joint of the robot arm is folded, It is possible to move the workpiece holder 180 provided in the effector 142 to a desired position at a high speed without using a drive motor or a precision speed reducer, thereby simplifying the structure of the apparatus and simplifying the control, Can be saved.

In addition, since the rectangular frame structure in which the four vertical frames 110 are erected at each corner of the square or rectangular work area R is compared with a conventional vertical frame having a triangular structure, The conveyor 10 can be easily disposed without interference or restriction in the form of penetrating between the vertical frames 110 and the work area R can be relatively wider than the scale of the apparatus.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various modifications and changes may be made without departing from the scope of the appended claims.

100 ... Parallel robot device 110 ... Vertical frame
111 ... rail 120 ... driving part
121 ... drive belt 122 ... drive motor
130 ... tension adjuster 140 ... moving part
160 ... Tension roller 170 ... Sensor part
180 ... workpiece chisel 181 ... working machine

Claims (7)

Four vertical frames 110 provided upright on each corner of the square or rectangular work area R and formed with vertically extending rails 111 on the inner side toward the center of the work area R;
A drive belt 121 which is inserted and rotated between two rollers 131 and 132 spaced apart from the upper and lower portions of the vertical frames 110 and a drive motor 122 for providing a rotational force to the drive belt 121 A driving unit 120 including the driving unit 120;
A slider 141 which moves up and down along the rail 111 in a state of being fastened to one side of the drive belt 121, an effector 142 horizontally disposed in the work area R, A moving part 140 including a link frame 143 linearly connected between the effector 142 and the moving part 140; And
And a controller for individually driving and controlling the respective driving motors 122 according to a user input signal to move the effector 142 in a horizontal state in the working area R. [
The method according to claim 1,
Spherical slider connection balls 144 projecting laterally are disposed on both sides of the slider 141,
The effector 142 is provided with a spherical effector coupling ball 145 protruding from both sides of each of the opposite sides of the vertical frame 110,
The moving unit 140 is connected to each side of the effector 142 and each slider 141 by paired two link frames 143 for each vertical frame 110, The rolling grooves 144a and 144b are formed at both ends so that one rolling groove 144a is rotatably connected to the slider connecting ball 144 and the rolling groove 144b of the other end is connected to the effector connecting ball 145 And wherein the first and second optical fibers are rotatably connected to each other.
3. The method of claim 2,
A sensor unit 140 disposed near the initial driving position of the slider 141 on the inner surface of the vertical frame 110 and sensing the slider 141 moved to the initial driving position and outputting a detection signal to the controller 170), < / RTI >
The controller receives the encoder value of each driving motor 122 from the driving unit 120 and calculates a moving distance of each slider 141. Based on the encoder value and the calculated moving distance value, Wherein each of the driving motors (122) is individually controlled to rotate so that each slider (141) moves to a set position.
The method of claim 3,
The initial driving position of the slider 141 is the upper end position of the rail 111 formed on the inner surface of the vertical frame 110,
The control unit determines that the slider 141 has moved to the initial driving position when a sensing signal is input from the sensor unit 170 and at the same time stops the rotation of the driving motor 122, (111). ≪ IMAGE >
5. The method of claim 4,
And a tension roller (160) disposed on an inner surface of the vertical frame (110) and pressing the one side of the driving belt (121) to rotate and rotate.
6. The method of claim 5,
The driving unit 120 includes:
A driving roller 131 and a driven roller 132 disposed above and below the vertical frame 110,
A lifting block 133 rotatably supporting the driven roller 132 by a bearing and having a screw hole 134 formed with a female screw on one side thereof,
A guide frame 135 fixed to the vertical frame 110 and supporting a side of the elevating block 133 to guide the elevating movement,
A stationary frame 136 fixed to the vertical frame 110 and having a through hole 137 at a position corresponding to the screw hole 134,
An adjusting screw 139 which penetrates through the through hole 137 and has an end portion inserted into the screw hole 134 and has a male screw thread engaging with the female screw thread to raise and lower the lifting block 133 along the rotating direction And a tension adjusting unit (130) for adjusting the tension of the robot.
7. The method according to any one of claims 1 to 6,
A first rotating frame 181 horizontally disposed below the effector 142 and rotating about a vertical axis line,
A first motor 182 fixed to one side of the effector 142 and providing a rotational force necessary for rotating the first rotating frame 181,
A second rotating frame 183 disposed upright on one side of the first rotating frame 181 and rotating about a horizontal axis line,
A second motor 184 fixed to one side of the first rotating frame 181 and providing a rotational force necessary for rotating the second rotating frame 183,
And a workpiece mount (180) mounted on one side of the second rotating frame (183) and configured to perform an operation set according to a control signal of the controller.

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