KR102034543B1 - A robot system component asssembly and control method thereof - Google Patents

Abstract

Disclosed is a control method of a robot system for assembling a component. The control method of the robot system for assembling the component according to one embodiment of the present invention recognizes a work space for assembling the component through a virtual vision coordinate system which is recognized through a camera of a vision unit, and is capable of automatically performing work such as component regulation, position correction, component joining, welding, product inspection, and the like by using a plurality of hanger robots mounted with hangers and one or more welding robots mounted with a welding machine, and specifically, each position coordinate in the vision coordinate system is compared and analyzed together with a separation coordinate value at a position separated from each other by a predetermined distance in a work space of a matching component, and an interference between the components is predicted and determined in advance to assemble in a state of avoiding the interference between the component by correcting the position of the component.

Description

Control method of robot system for assembly of parts {A ROBOT SYSTEM COMPONENT ASSSEMBLY AND CONTROL METHOD THEREOF}

The present invention relates to a method of controlling a robot system for assembling parts, and more specifically, a work space for assembling parts using a position coordinate on a virtual vision coordinate system recognized through a camera of a vision unit. It relates to a control method of a robot assembly for component assembly that can be assembled in a state in which interference between components is avoided by matching the position on the model coordinate system.

In general, in the industrial field, in order to assemble parts, assembly work is performed by using a welding facility in which the parts are regulated through a dedicated jig.

That is, in the process of assembling parts, a worker places each part on a dedicated jig to detect a missing part, a seating state, etc. through a sensor, and then fixes each part with a clamper, and a welding robot is determined. Enter the welding machine along the path and proceed to welding.

However, in the conventional case, since the worker fixes the parts on the fixed dedicated jig and the welding robot enters the welding machine along the predetermined path to perform welding work, it does not actively respond to the forming tolerances of the parts. There is a problem.

As such, when welding defects occur between parts due to molding tolerances of the parts or a mistake of an operator, reinforcing welding may be performed manually, or the waste may be disposed of as a defective product.

On the other hand, the dedicated jig as described above is produced as a dedicated equipment of the corresponding parts, each time to develop a new model must be newly produced, and this has the disadvantage that the equipment investment costs, such as jig production costs and electrical equipment construction every time.

The matters described in this Background section are intended to enhance the understanding of the background of the invention, and may include matters not previously known to those of ordinary skill in the art.

An embodiment of the present invention recognizes a workspace for assembling parts through a virtual vision coordinate system that is recognized through a camera of the vision unit, by using a plurality of hanger robots and one or more welding robots to regulate the parts, position correction, parts And to provide a control method of the robot assembly for component assembly that can automatically perform tasks such as welding and product inspection.

In addition, an embodiment of the present invention by comparing the parts matched with each other in the work space at a predetermined distance from each other, by comparing each position coordinates on the vision coordinate system with the spaced coordinate values to predict the interference between the parts in advance to determine the position of the parts The purpose of the present invention is to provide a control method for a robot assembly system for assembling parts by assembling them in a state of avoiding interference between parts.

In one or more embodiments of the present invention, a vision system having a camera, a plurality of hanger robots having respective hangers, at least one welding robot having a welder, a vision controller, and a robot system for assembling parts including a robot controller. In the control method of, the three-point position coordinates on the vision coordinate system generated by scanning the position of the correction tool on each hanger robot according to the minimum three-point behavior of each hanger robot with the camera and the corresponding three-point position coordinates on the robot coordinate system A first correction step (S1) of correcting the robot coordinate system with a correction value calculated to match the vision coordinate system and the robot coordinate system; A part regulation step of controlling each hanger by gripping each part to be assembled through the hanger of each hanger robot (S2); A first correction value calculated by calculating a coordinate difference value between the correction tool on each hanger robot and a component regulated on each hanger with a camera of a vision unit, and calculating the coordinate difference value between the correction tool and each position coordinate on the vision coordinate system of the part; A second correction step S3 of correcting the robot coordinate system corrected in the correction step and setting the robot coordinate system based on the component; Control parts of the hanger robot to apply the distance coordinates to the other parts assembled to one of the parts that are matched for assembly, the parts to move the parts to a distance spaced apart from each other in the work space Step S4; When the parts are spaced apart from each other in the work space by the camera of the vision unit, the vision controller generates respective position coordinates on the vision coordinate system of the parts, and compares the respective position coordinates and the spaced coordinate values together. Analyze and predict the interference between the parts to calculate a third correction value for the coordinate interference value of each of the position coordinates of the parts, wherein the position coordinates for the other one matching the one of the parts, A third correction step S5 of correcting a position by applying three correction values; A part matching step (S6) of controlling the hanger robot for regulating the other part as a hanger and returning the other part to the one part by a spaced coordinate value in a workspace to match the parts together; Welding step (S7) for welding the weld of the matched parts by controlling the at least one welding robot and the welding machine; And an inspection step (S8) of performing a defect inspection according to a tolerance range by comparing a position coordinate on a vision coordinate system generated by scanning a product welded on the welded parts of the parts with the camera and model data coordinates on a model coordinate system. can do.

In the first correction step S1, when the vertex of the correction tool on each hanger robot is scanned according to the minimum three-point behavior of each hanger robot on the work space through the camera of the vision unit, the vision controller vertices of the correction tool. Generate a three-point position coordinate on the vision coordinate system, and compare the three-point position coordinate on the robot coordinate system with respect to the vertex of the correction tool received from the robot controller and compare the three-point position coordinate on the vision coordinate system with the coordinate difference value. Calculating a first correction value for the robot, and applying the first correction value to the robot coordinate system set in the robot controller to correct and set the first correction value.

That is, the first correction step (S1) is a step of the robot controller to control each hanger robot three-point movement to any three-point position in the workspace (S11); Outputting image information by scanning a vertex of a correction tool fixed to an arm tip of each hanger robot with respect to an arbitrary 3-point position according to the 3-point behavior of each hanger robot through the camera of the vision unit (S12); Analyzing image information of the correction tool for any three-point position of each hanger robot to generate first, second and third position coordinates on a vision coordinate system for a vertex of the correction tool (S13); Receiving (S14) first, second and third position coordinates on the robot coordinate system for the vertex of the correction tool at any three point positions of the hanger robots; Calculating a first correction value for the coordinate difference values between the first, second, and third position coordinates on the robot coordinate system and the first, second, and third position coordinates on the vision coordinate system (S15); And transmitting the first correction value to the robot controller to correct and set the robot coordinate system to the first correction robot coordinate system (S16).

The second calibration step S3 is performed by scanning the vertices of the calibration tool on each hanger robot and any one point on the parts regulated on each hanger in the work space through the camera of the vision unit. Generate each position coordinate in the vision coordinate system for a vertex of the correction tool and any one point on the part, calculate a second correction value for the coordinate difference value of each position coordinate, and in the first correction step, the robot controller The method may be performed by applying the second correction value to the corrected robot coordinate system and correcting and setting the second corrected robot coordinate system again.

Here, the second calibration robot coordinate system is composed of a coordinate system in which a reference coordinate for controlling each hanger robot is moved from a robot rotation center point (RRCP), which is a vertex of the calibration tool, to a component rotation center point (PRCP), which is an arbitrary point on the part. Can be.

That is, the second correcting step (S3) includes the step of the robot controller controlling each hanger robot to position the parts regulated on each hanger on each hanger robot at a set position on the work space (S31); Outputting image information by scanning a vertex of a correction tool fixed to an arm tip of each hanger robot on a work space and an arbitrary point of a part restricted to each hanger through a camera of the vision unit (S32); Analyzing first image information about a vertex of the correction tool to generate a first position coordinate which becomes a robot rotation center point (RRCP) on a vision coordinate system (S33); Analyzing the image information of any one point of the part and generating a second position coordinate which becomes a part rotation center point (PRCP) on a vision coordinate system (S34); Calculating a second correction value for a coordinate difference value of the first and second position coordinates on the vision coordinate system (S35); And transmitting the second correction value to the robot controller, correcting and setting the robot coordinate system corrected in the first correction step to a second correction robot coordinate system (S36).

The third correcting step (S5) includes a step in which one hanger robot places one part on a work space with model data coordinates on a model coordinate system set in a drawing program (S51); Positioning another part assembled by the other hanger robot on the work part by applying a spaced coordinate value of a predetermined distance from the model data coordinates set in the drawing program (S52); Outputting image information by scanning mutual matching points for the one component and the other component through the camera of the vision unit; Generating first and second position coordinates of each matching point in a state spaced apart from the vision coordinate system by analyzing image information about the one component and the other component (S54); Comparing the first and second positional coordinates on a vision coordinate system with the spaced coordinate values to determine whether there is interference between the one component and the other component as coordinate interference values (S55); Calculating a third correction value for the coordinate interference value when an interference occurs between the one component and the other component (S56); And transmitting the third correction value to the robot controller and applying the third correction value to a position coordinate on the robot coordinate system with respect to the other component to correct the position of the other component in the working space (S57).

Here, the model data coordinates may be configured as coordinate values of a part model in which data of a reference pin, which is a coordinate reference on a vision coordinate system, is inserted into model data on a drawing program of the part, and the position coordinate of the reference pin is a reference coordinate. .

An embodiment of the present invention recognizes a workspace for assembling parts through a virtual vision coordinate system recognized through the camera of the vision unit, using a plurality of hangers equipped with a hanger and at least one welding robot equipped with a welder Parts regulation, position compensation, parts joining, welding and product inspection can be done automatically in one process.

That is, in the embodiment of the present invention, since the assembly of parts is performed using a plurality of hanger robots and one or more welding robots in a work space recognized as a vision coordinate system, a facility such as a conventional complicated dedicated jig unit is unnecessary, and various The compatibility of the parts of the specification can save the electrical equipment cost for assembly, there is an advantage that does not need to provide a separate equipment such as inspection jig for defect inspection of the product.

In addition, an embodiment of the present invention compares the parts matched with each other in the work space by a predetermined distance from each other, each position coordinates on the vision coordinate system recognized by the camera of the vision unit with the comparison of the separation coordinates to compare the interference between the parts Predictive determination of the pre-correction, and by assembling the parts can be assembled in a state of avoiding the interference between the parts.

As a result, it is possible to prevent deformation scattering caused by interference assembly due to interference between parts and quality distribution of the assembled product, and it is not necessary to manufacture a dedicated inspection jig, thereby reducing jig production costs.

In addition, the effects that can be obtained or predicted by the embodiments of the present invention will be disclosed directly or implicitly in the detailed description of the embodiments of the present invention. That is, various effects predicted according to an embodiment of the present invention will be disclosed in the detailed description to be described later.

1 is an overall configuration diagram of a robot system for assembly of parts to which a control method according to an embodiment of the present invention is applied.
2 is a perspective view of a vision unit on a robot system for assembly of parts to which a control method according to an embodiment of the present invention is applied.
3 is a control block diagram of a robot system for assembly of parts to which a control method according to an exemplary embodiment of the present invention is applied.
4 is a process diagram according to a control method of a robot system for assembly of parts according to an embodiment of the present invention.
5 is a control flowchart of a first correction step S1 according to a control method of a component assembly robot system according to an exemplary embodiment of the present invention.
6 is an exemplary view of a first correction step S1 according to a control method of a robot system for assembly of parts according to an embodiment of the present invention.
7 is a control flowchart of a second correction step S3 according to a control method of a robot system for assembly of parts according to an embodiment of the present invention.
8 is an exemplary view illustrating a second correction step S3 according to a control method of a robot system for assembly of parts according to an embodiment of the present invention.
9 is a control flowchart of a third correction step S5 according to a control method of a robot system for assembly of parts according to an embodiment of the present invention.
10 is an exemplary view of a third correction step S5 according to a control method of a robot system for assembly of parts according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings and the detailed description will be described in detail the configuration and operating principle of the embodiment of the robot assembly for assembly and control method according to an embodiment of the present invention.

However, the drawings shown below and the following detailed description relate to one preferred embodiment among various embodiments for effectively explaining the features of the present invention, and the present invention is not limited to the following drawings and descriptions.

In addition, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to a user's or operator's intention or custom, and the definitions should be interpreted based on the contents throughout the technology of the present invention. .

In addition, the embodiments of the present invention will be used to appropriately modify, integrate, or separate the terminology so that those skilled in the art to which the present invention pertains may clearly understand the core technical features. Thereby, this invention is not limited at all.

In addition, in order to clearly describe the embodiments of the present invention, parts irrelevant to the description are omitted, and the same or similar components will be described with the same reference numerals throughout the specification, and the names of the components are described in the following description. The first, second, and the like are classified to have the same names, and are not necessarily limited to the order thereof.

1 is an overall configuration diagram of a robot assembly for component assembly according to an embodiment of the present invention, Figure 2 is a perspective view of a vision unit applied to the robot assembly for component assembly according to an embodiment of the present invention, Figure 3 is a present invention A control block diagram of a robot system for assembly of parts according to an embodiment of the present invention.

1 to 3, a robot assembly for parts assembly according to an embodiment of the present invention includes a vision unit (VU), first, second, and third hanger robots R1 installed on a work space where parts are assembled. (3) hanger robots (R1, R2, R3) composed of (R2) and (R3), and one welding robot (R4), and a vision controller (VC) for controlling the vision unit (VU). And a robot controller RC for controlling the three hanger robots R1, R2, and R3 and the welding robot R4.

The vision unit VU includes a frame 13 installed at one side of the work space, a reference pin 15 configured at one side of the frame 13 to serve as a coordinate reference, and a vertical direction with respect to the frame 13. The first linear rail LR1 moving in the direction, the second linear rail LR2 moving in the left and right direction on the first linear rail LR1, and moving forward and backward on the second linear rail LR2, The first and second linear rails LR1 and LR2 together with the camera 11 is installed so as to enable the overall six-axis movement.

The frame 13 has two pillar beams 13a, which are formed as square beams, fixedly installed at both sides of the work space, and an upper beam 13b is installed by connecting the upper ends of both pillar beams 13a.

In addition, the frame 13 may additionally install additional support beams for fixing both pillar beams 13a to the bottom surface, which will be omitted in the embodiment of the present invention.

Two reference pins 15 are respectively provided on both sides of the lower surface of the upper beam 13b, each end of which is precisely processed.

The first linear rail LR1 is disposed between the two pillar beams 13a and configured to be rotatable while moving up and down along the pillar beams 13a through the driving means.

The driving means has a first motor (M1) is fixed to the front center of the upper beam (13b), both connecting shafts (41) are rotatably installed on both sides of the front of the upper beam (13b), respectively, the upper beam It is configured to be capable of transmitting power with the drive shaft of the first motor (M1) through the gear box (GB) installed in the front center of the front (13b).

In addition, both side guide rails 43 (one side not shown) are configured in the vertical direction along each of the inner side surfaces in the longitudinal direction of the two pillar beams 13a, and both screw shafts 45 are the lengths of the pillar beams 13a. It is installed rotatably in the up and down direction along each front direction.

The two screw shafts 45 are connected to each of the outer end portions of the two connecting shafts 41 so as to be capable of power transmission through a gear box GB installed at each upper end of each of the upper pillar beams 13a. Receives the rotational power of the first motor (M1).

Here, the gear box GB means a box in which various gears for converting and transmitting the rotational power of the first motor M1 by 90 degrees are incorporated. In this case, the various gears applied therein are straight and curved. Bevel gears, worm gears, worm gears, hypoid gears, etc. may be applied, but the present invention is not limited thereto, and may be applicable as long as the gear set converts the rotational power of the motor at a predetermined angle.

The guide rails 43 and the screw shafts 45 on the both side beams 13a are engaged with the screw shafts 45, respectively, so as to move upward and downward along the guide rails 43, respectively. The falling sliders 51 and 53 are configured.

Here, the second motor M2 including the speed reducer 55 is installed on one side lowering slider 51, and the bearing block BB is provided on the other side lowering slider 53.

In addition, a rotation plate 57 is installed between the two lowering sliders 51 and 53 at both ends of the reducer 55 and the bearing block BB through both ends, and the rotation plate 57 is connected to the second motor ( The rotational power of M2) is decelerated through the reducer 55 and is rotated 360 degrees with respect to both of the elevating sliders 51 and 53.

Here, the first linear rail (LR1) is installed on the rotating plate 57 and rotates with the rotating plate 57, the first sliding slide movement in the left and right directions in the rail direction on the first linear rail (LR1) One slider SR1 is comprised.

The second linear rail LR2 is provided with a central portion on the first linear rail LR1 through the first slider SR1, and slides in the front and rear directions in the rail direction on the second linear rail LR2. The second slider SR2 is configured.

In this case, the second linear rail LR2 is installed on the first linear rail LR1 through the first slider SR1, and rotates together with the rotating plate 57.

Here, the first and second linear rails (LR1) (LR2) may be applied to a linear rail of a conventional motor and a screw driving method, but is not necessarily limited thereto, the magnetic flux of the magnetic flux and the magnet by the current supplied to the coil A linear motor using thrust generated by the action of the magnetic flux can be applied.

The camera 11 may be installed on the second linear rail LR2 through a second slider SR2, and a 3D vision camera may be applied to acquire a 3D image for generating a spatial coordinate of the subject.

The camera 11 moves forward and backward along the second linear rail LR2 and photographs a subject while moving in all six axes along with the movement of the first and second linear rails LR1 and LR2. Output video information.

That is, the vision unit (VU) recognizes the front end of the reference pin 15 through the camera 11, and uses this as a reference coordinate (origin coordinate) to recognize the working space as a virtual vision coordinate system, work Each robot R1, R2, R3 and parts P1, P2, P3, etc., which are located in the space, are recognized by the camera 11 and output image information using the reference pin 15 as reference coordinates. .

The first, second, and third hanger robots R1, R2, and R3 are hangers H1 and H2 for component regulation at the tip of an arm of an articulated robot controlled by a six-axis servomotor. (H3) is installed and configured, and is configured on the front one side and both sides of the vision unit (VU) on the work space, respectively.

In the exemplary embodiment of the present invention, the hanger robots R1, R2, and R3 are limited to three, but may be configured as two or four, and may be determined at a level capable of efficient operation in consideration of the number of parts assembled with the work space. Can be.

In addition, the welding robot (R4) is configured by the welding machine (W) is installed on the tip of the arm of the articulated robot controlled by the drive of the six-axis servo motor, it is configured on the rear side of the vision unit (VU) in the working space. .

At this time, the welding machine (W) is not limited to the welding method such as an arc welding machine, resistance welding machine, friction stir welding machine, self-piercing riveting jointer, laser welding machine, welding properties of the part material, structural characteristics of the welding portion, operability in the work space, etc. In consideration of this can be applied according to the efficient welding method.

In the exemplary embodiment of the present invention, the welding robot R4 is limited to one, but may be configured as two or three, and may be determined at a level capable of efficient operation in consideration of a work space and a welding method applied thereto.

In addition, in the embodiment of the present invention, the articulated robot is limited to drive control by a 6-axis servo motor, but the present invention is not limited thereto, and it may be difficult to select the position of the parts P1, P2, P3 or the welding machine W. The number of servomotors can be determined in the range not found.

Here, the hanger robot (R1, R2, R3) and the welding robot (R4) is only different names to distinguish according to the intended use, may be composed of the same robot, the robot controller (RC) of the attitude control The overall operation is controlled by the control signal.

The vision controller VC is provided at an external side of the work space to store overall kinematic setting information of the vision unit VU for position control of the camera 11, and each robot R1, R2, and R3 and parts thereof. Control the overall operation for position control of the camera 11 to recognize (P1, P2, P3), and each robot (R1, R2, R3) and parts (P1, P2, P3) recognized through the camera 11 Create accurate position information in the work space through image information such as) or set the correction value through coordinate correction.

The vision controller VC may be configured with at least one processor utilizing a program and data for position control of the camera 11, the position control of the camera 11 is a kinematic setting of the vision unit (VU) An ideal theoretical value calculated based on information includes a plurality of moving points for sequentially moving the camera 11 and at least one posture that can be taken at each moving point.

In addition, the vision controller VC sets the workspace to the virtual vision coordinate system recognized by the camera 11 based on the reference pin 15 on the vision unit VU as a coordinate reference, and is located on the workspace. Position correction for each robot R1, R2, R3 and parts P1, P2, P3 based on the coordinate values on the vision coordinate system of each robot R1, R2, R3 and parts P1, P2, P3. The calibration may be performed and at least one operation may be controlled through the position of the camera 11, the movement to a desired position, and the posture control.

Here, the vision coordinate system Vx, Vy, Vz is a vision controller VC, through the camera 11 of the vision unit (VU) on the basis of any one point in the workspace in virtual space coordinates. As the coordinate system to display, the vertex of the reference pin 15 is determined by the position of each robot R1, R2, R3 or the parts P1, P2, P3 recognized by the camera 11 in the work space for assembling the parts. It can be displayed in spatial coordinates as a reference.

Such a vision controller (VC) is a plurality of processors utilizing programs and data for the overall coordinate generation and coordinate correction of each robot (R1, R2, R3) and parts (P1, P2, P3) in the workspace for parts assembly As the main controller configured, may be a programmable logic controller (PLC), a PC, a WORKSTATION, or the like.

The robot controller RC is provided at an external side of the work space to store kinematic setting information for the posture control of the robot, and controls the overall operation of the posture control of the robot for assembly and welding of parts.

The robot controller RC may be configured with at least one processor utilizing a program and data for attitude control of the robot, and the attitude control of the robot corresponds to an ideal theoretical value calculated based on the kinematic setting information of the robot. It includes a plurality of movement points for moving the robot sequentially and at least one posture that can be taken at each movement point.

In addition, the robot controller RC performs calibration for behavior and attitude control of each robot R1, R2, R3, and R4 in a work space based on the robot coordinate system, and each robot R1, R2, R3, and R4. At least one task can be controlled through the position of the), the movement to the desired position and the posture control.

Here, the robot coordinate systems Rx, Ry, and Rz are unique coordinate systems of the robot for recognizing the behavior of each of the hangers H1, H2, and H3 through the robot controller RC, and are coordinate systems programmed in the robot controller RC. The position of the vertex of the correction tool (not shown) on the robot arm can be displayed in spatial coordinates.

In addition, the robot controller RC operates each hanger H1, H2, H3 on the three hanger robots R1, R2, R3, and the welding machine W on one welding robot R4. It includes a control logic to control the.

Meanwhile, in the practice of the present invention, model coordinate systems Mx, My, and Mz are used, and the model coordinate systems Mx, My, and Mz are used to change the shape of a part model on a drawing program of each component P1, P2, and P3. As a coordinate system expressed in spatial coordinates, model data coordinates (that is, car) having a reference pin 15, which is a coordinate reference on a vision coordinate system, inserted into model data on a drawing program and using the position coordinates of the reference pin 15 as reference coordinates. also called -line coordinates).

On the other hand, the robot assembly for component assembly according to an embodiment of the present invention may further include a monitor 21 and the alarm 31.

The monitor 21 may display operation information and result information of each of the hanger robots R1, R2, and R3 and the welding robot R4 generated during the operation of the robot controller RC or the vision controller VC. have. That is, the monitor 21 may display image information captured by the camera 11 of the vision unit VU and movement path information of each hanger robot R1, R2, R3 and the welding robot R4 as coordinate values. In addition, the position information of each component P1, P2, and P3 in the workspace may be displayed as a coordinate value.

In addition, the monitor 21 may display defect information by text or the like under the control of the robot controller RC and the vision controller VC.

The type of monitor 21 is irrelevant as long as it can display operation information and result information. For example, the monitor 21 may include a liquid crystal display (LCD), an organic light emitting display (OLED), an electrophoretic display (EPD), and a light emitting diode (Light Emitting). Diode (LED) may be one of the display devices.

In addition, the alarm 31 outputs failure information of the parts P1, P2, and P3 under the control of the robot controller RC or the vision controller VC, wherein the failure information is the parts P1 and P2. Or P3) or information for informing a worker that a defect has occurred in the product, for example, the defect information may be made of voice, graphics, light, or the like.

Hereinafter, the vision unit VU, three hanger robots R1, R2, and R3 and each hanger H1, H2, and H3 in the work space through the parts assembly robot system having the configuration as described above. And a vision controller (VC) and a robot controller (RC) of a component assembly robot system for assembling a plurality of components P1, P2, and P3 using one welding robot R4 and a welding machine W. The control method will be described.

4 is a control flowchart of a robot system for assembly of parts according to an exemplary embodiment of the present invention.

Referring to Figure 4, the control method of the robot assembly for component assembly according to an embodiment of the present invention, the first correction step (S1), the part regulation step (S2), the second correction step (S3), the component separation step (S4) ), The third correction step (S5), the part matching step (S6), the welding step (S7), and the inspection step (S8), a total of eight steps are made by sequentially proceeding the work process.

Each of these steps S1 to S8 is mainly described with the robot controller RC and the vision controller VC communicating with the robot controller RC.

First, the first correction step S1 is performed while the first, second, and third hanger robots R1, R2, and R3 each move three points on the work space under the control of the robot controller RC. The vertex of each of the correction tools T on the first, second, and third hanger robots R1, R2, and R3 is controlled by the vision controller VC to control the camera 11 of the vision unit VU. In the following example, the vision controller VC generates three-point position coordinates Vx, Vy, and Vz on the vision coordinate system for the vertices of the respective calibration tools T.

The vision controller VC is a corresponding three-point position coordinates (Rx, Ry, Rz) on the robot coordinate system with respect to the vertex of the correction tool (T) received from the robot controller (RC) and three-point position coordinates on the vision coordinate system ( Vx, Vy, and Vz) are compared to calculate a first correction value consisting of correction coordinate values for the coordinate difference values.

The vision controller VC transmits a first correction value to the robot controller RC, applies the first correction value to a robot coordinate system set in the robot controller RC, and corrects and sets the correction value in the first correction robot coordinate system. .

The first correction step S1 corrects the robot coordinate system set as the intrinsic coordinate system in the robot controller RC with the first correction value to match the vision coordinate system.

5 is a control flowchart of a first correction step S1 according to a control method of a component assembly robot system according to an exemplary embodiment of the present invention, and FIG. 6 is a control method of a component assembly robot system according to an exemplary embodiment of the present invention. Fig. 1 shows an example of the first correction step S1 according to the present invention.

The first correction step S1 will be described in detail with reference to FIGS. 5 and 6.

That is, in the first correction step S1, the robot controller RC sequentially controls the first, second, and third hanger robots R1, R2, and R3, so that any three-point positions on the work space are provided. 3-point behavior with (S11)

At this time, the vision controller (VC) controls the vision unit (VU) to any three-point position according to the three-point behavior of the first, second, third hanger robot (R1) (R2) (R3). The vertex of each correction tool T fixed to each arm tip of the first, second, and third hanger robots R1, R2, and R3 is scanned through the camera 11 to output image information. S12)

Subsequently, the vision controller VC analyzes the image information of each of the correction tools for any three-point positions of the first, second, and third hanger robots R1, R2, and R3 to correct each of the correction tools. First, second and third position coordinates Vx, Vy, and Vz on the vision coordinate system for the vertex of (T) are generated.

In this case, the first, second and third position coordinates (Vx, Vy, Vz) on the vision coordinate system are Vx ₁ , Vy ₁ , Vz ₁ , Vx ₂ , Vy ₂ , Vz ₂ , and Vx ₃ , Vy ₃ , 3D coordinates, which are three-dimensional spatial coordinates represented by Vz ₃ , may be generated.

In addition, the vision controller VC may include the first, second, and third hanger robots R1, R2, and R3 in the robot coordinate system with respect to the vertex of the correction tool T at any three point positions. Second and third position coordinates Rx, Ry, and Rz are received from the robot controller RC. (S14)

In this case, the first, second and third position coordinates (Rx, Ry, Rz) on the robot coordinate system are Rx ₁ , Ry ₁ , Rz ₁ , Rx ₂ , Ry ₂ , Rz ₂ , and Rx ₃ , Ry ₃ , 3D coordinates, which are three-dimensional spatial coordinates represented by Rz ₃ , may be generated.

Here, although the arbitrary behaviors of the first, second, and third hanger robots R1, R2, and R3 are limited to three points, the first, second, and third position coordinates Vx on the vision coordinate system Vx. , Vy, Vz and first, second, and third position coordinates Rx, Ry, and Rz on the robot coordinate system, respectively, to generate 3D coordinates, which are three-dimensional spatial coordinates, but are not necessarily limited thereto. If necessary for the reliability of the coordinate generation can be achieved through the behavior of three or more points.

Thereafter, the vision controller VC includes first, second and third position coordinates Rx, Ry and Rz on the robot coordinate system and first, second and third position coordinates Vx, Vy and Vz on the vision coordinate system. ) Is calculated to calculate a first correction value comprising correction coordinate values with respect to the coordinate difference value (S15).

When the vision controller VC sends the first correction value to the robot controller RC, the robot controller RC applies the first correction value to the robot coordinate system and corrects it with the first correction robot coordinate system to reset the robot coordinate system. (S16)

As shown in FIG. 1, the component control step S2 includes the first, second, and third hanger robots R1, R2, R3, and the first, second, and third robots. The first, second, and third parts P1 (P2) to be assembled by controlling the first, second, and third hangers H1, H2, and H3 of the third hanger robot R1, R2, and R3. (P3) is gripped and regulated.

The second correction step S3 is a vertex of each correction tool T on the first, second, and third hanger robots R1, R2, and R3 on the work space under the control of the vision controller VC. And any one point D on each of the parts P1, P2, and P3 regulated on the first, second, and third hangers H1, H2, and H3, the camera of the vision unit VU. Scanning through (11), the vision controller VC causes each position coordinate on the vision coordinate system for the vertex of each correction tool T and any one point D on each component P1, P2, P3. Vxt, Vyt, Vzt) (Vxd, Vyd, Vzd).

The vision controller VC calculates a second correction value as a correction coordinate value for a coordinate difference value of each position coordinate Vxt, Vyt, Vzt (Vxd, Vyd, Vzd).

The vision controller VC sends a second correction value to the robot controller RC and applies the second correction value to the first correction robot coordinate system corrected to the robot controller RC in the first correction step S1. By the second calibration robot coordinate system.

The second correction step S3 corrects the robot coordinate system for the behavior of the first, second, and third hanger robots R1, R2, and R3 to a second correction value, thereby providing each hanger robot R1, R2, and R3. ) Will behave based on each component (P1, P2, P3).

Here, the second correction robot coordinate system is a robot rotation center point that is a vertex of each of the correction tools (T) for each reference coordinate for controlling the first, second, and third hanger robots R1, R2, and R3. It consists of a coordinate system moved from RRCP to the component rotation center point PRCP, which is an arbitrary point D on the component P1, P2, P3.

7 is a control flowchart of a second correction step (S3) according to a control method of a component assembly robot system according to an exemplary embodiment of the present disclosure, and FIG. 8 is a control method of a component assembly robot system according to an exemplary embodiment of the present disclosure. An illustration of the second correction step S3 according to the present invention.

The second correction step S3 will be described in detail with reference to FIGS. 7 and 8.

That is, in the second correction step S3, the robot controller RC sequentially controls the first, second, and third hanger robots R1, R2, and R3 so that the first, second, and third devices may be controlled. The parts P1, P2, and P3 regulated by the hangers H1, H2, and H3 are positioned at the set positions on the work space (S31).

The vision controller VC controls the vision unit VU, and each of the correction tools T fixed to the arm tips of the first, second, and third hanger robots R1, R2, and R3 on the work space. Scans through the camera 11 any vertex D of any of the components P1, P2, P3 regulated at the vertices of the first, second, and third hangers H1, H2, and H3. And outputs the image information. (S32)

The vision controller VC analyzes the image information of the vertices of each of the correction tools T and generates respective first position coordinates Vxt, Vyt, and Vzt, which become respective robot rotation center points RRCP on the vision coordinate system. (S33)

In this case, each of the first positional coordinates Vxt, Vyt and Vzt on the vision coordinate system is represented by Vxt ₁ , Vyt ₁ , Vzt ₁ , Vxt ₂ , Vyt ₂ , Vzt ₂ , and Vxt ₃ , Vyt ₃ , Vzt ₃ . The 3D coordinates may be generated as 3D coordinates.

Subsequently, the vision controller VC analyzes image information about any one point of each of the components P1, P2, and P3, so that each second position coordinate (PRCP) becomes a center point of rotation of each component on the vision coordinate system ( Vxd, Vyd, and Vzd) are generated (S34).

In this case, each of the second positional coordinates (Vxd, Vyd, Vzd) on the vision coordinate system is represented by Vxd ₁ , Vyd ₁ , Vzd ₁ , Vxd ₂ , Vyd ₂ , Vzd ₂ , and Vxd ₃ , Vyd ₃ , Vzd ₃ . The 3D coordinates may be generated as 3D coordinates.

Thereafter, the vision controller VC calculates a second correction value including a correction coordinate value for a coordinate difference value of the first and second position coordinates Vxt, Vyt, and Vzt (Vxd, Vyd, Vzd) on the vision coordinate system. (S35)

When the vision controller VC sends the second correction value to the robot controller RC, the robot controller RC converts the first correction robot coordinate system corrected in the first correction step S1 into a second correction robot coordinate system. Set the robot coordinate system again by calibrating with (S36).

In the component separation step S4, the robot controller RC controls the first, second, and third hanger robots R1, R2, and R3 to match the first component P1 for assembly. The second and third parts P2 and P3 are sequentially applied to the second and third parts P2 and P3 to be spaced apart by a predetermined distance from the first part P1 in the workspace. Move each).

The third correction step S5 may be spaced apart from the first part P1 and the first part P1 of the workspace by the control of the vision controller VC in the part separation step S4. The scanned second and third parts P2 and P3 through the camera 11 of the vision unit VU, the vision controller VC causes the first, second, and third parts P1 to pass through. Each positional coordinate (Vx, Vy, Vz) on the vision coordinate system of (P2) (P3) is generated.

The vision controller VC compares and analyzes each of the position coordinates Vx, Vy, and Vz and the values of the spaced coordinates Dx, Dy, and Dz together to form second and third components for the first component P1. Predict the interference of (P2) (P3), and for the coordinate interference value of the respective position coordinates (Vx, Vy, Vz) of the second and third components (P2) (P3) with respect to the first component (P1) Each third correction value is calculated from the correction coordinate values.

The vision controller VC sends each of the third correction values to the robot controller RC and coordinates each position with respect to the second and third parts P2 and P3 matching the first part P1. And correcting each position of the second and third components P2 and 3 with respect to the first component P1 by applying respective third correction values to (Vx, Vy, Vz).

In the third correction step S5, the second and third parts P2 and P3 matched with respect to the first part P1 in the work space are positioned on the vision coordinate system on a position spaced apart from the first part P1 by a predetermined distance. Predict the interference between each component (P1, P2, P3) by using the position coordinates (Vx, Vy, Vz) in advance to determine the position coordinates of each component (P1, P2, P3) on the vision coordinate system and the model coordinate system (Vx, Position correction is made to match Vy, Vz) (Mx, My, Mz).

FIG. 9 is a control flowchart of a third correction step S5 according to a control method of a component assembly robot system according to an exemplary embodiment of the present disclosure, and FIG. An illustration of the third correction step S5 according to the method.

9 and 10, the third correction step S5 will be described in detail for each step.

That is, in the third correction step S5, the robot controller RC controls the first hanger robot R1 so that the first component P1 may be model data coordinates Mx, My, and the like on the model coordinate system set in the drawing program. Mz) in the workspace on the vision coordinate system (S51).

Subsequently, the robot controller RC sequentially controls the second and third hanger robots R2 and R3 so as to assemble the second and third parts P2 and P3 assembled to the first part P1. A distance coordinate (Dx, Dy, Dz) value of a position spaced a certain distance from the model data coordinates (Mx, My, Mz) on the model coordinate system set in the drawing program is applied and placed in the workspace on the vision coordinate system (S52).

Thereafter, the vision controller VC controls the vision unit VU to control the first component P1 and the second and third components P2 and P3 matching the first component P1. Each matching point is scanned through the camera 11 to output image information (S53).

The vision controller VC analyzes image information of each matching point of the first, second, and third components P1, P2, and P3, and analyzes the image information of each matching point in a state spaced apart from the vision coordinate system. The first, second, and third position coordinates Vx, Vy, and Vz are generated (S54).

In this case, each of the first, second, and third position coordinates Vx, Vy, and Vz on the vision coordinate system is Vx ₁ , Vy ₁ , Vz ₁ , Vx ₂ , Vy ₂ , Vz ₂ , and Vx ₃ , Vy. ₃ , Vz ₃ may be generated as a 3D coordinate, which is a three-dimensional space coordinate.

Subsequently, the vision controller VC compares the first, second, and third positional coordinates Vx, Vy, and Vz on the vision coordinate system with the spacing coordinates Dx, Dy, and Dz, to determine a coordinate interference value. As a result, it is determined whether the second and third components P2 and P3 have interference with the first component P1.

At this time, the vision controller VC is a corrected coordinate value for the coordinate interference value when the interference occurs between the second component P2 or the third component P3 with respect to the first component P1. (P56), the third correction value is calculated.

When the vision controller VC sends the third correction value to the robot controller RC, the robot controller RC interferes with the first component P1 or the second component P2 or the third component P3. The third correction value is applied to the position coordinates Rx, Ry, and Rz on the robot coordinate system to correct the position on the work space of the component P2 or P3 that interferes with the first component P1. )

In this third correction step S5, the model data coordinates Mx, My, and Mz are transmitted to each model data on the drawing program of the first, second, and third components P1, P2, and P3. By inserting the data of the reference pin 15, which is the coordinate reference on the coordinate system, the position coordinates of the reference pin 15 may be composed of the coordinate values of the part model.

In the component matching step S6, the robot controller RC regulates the second and third parts P2 and P3 to the hangers H2 and H3, respectively. By sequentially controlling the R3, the second and third parts P2 and P3 are sequentially returned by the distance coordinates Dx, Dy, and Dz with respect to the first part P1 in the workspace. The first, second, and third components P1, P2, and P3 are matched with each other at each matching point.

Subsequently, in the welding step S7, the robot controller RC controls the welding robot R4 and the welding machine W to match the first, second, and third parts P1 (P2) ( Each welding part of P3) is welded and assembled.

In the inspection step S8, the vision controller VC controls the vision unit VU to weld each welded part of the first, second, and third components P1, P2, and P3. Is scanned by the camera 11 and outputs the image information, the vision controller VC converts the position coordinates Vx, Vy, Vz on the vision coordinate system for the product to the model data coordinates Mx, My, Mz on the model coordinate system. ) And determine whether the coordinate difference is within the tolerance range and proceed with the defect inspection.

Therefore, the robot system and the control method for assembling parts according to an embodiment of the present invention automatically in a plurality of parts (P1, P2, P3) for assembling each other in a work space recognized as a vision coordinate system by the vision unit (VU) After assembling by welding in the state that is regulated and corrected, the assembly work can be performed at one time until the product inspection.

That is, the robot assembly and control method for parts assembly according to an embodiment of the present invention, the first, second, third hanger robot (R1) (R2) (R3) and the welding robot (in a work space that is recognized as a vision coordinate system) As R4) is used to assemble parts (P1, P2, P3), it is not necessary to install complicated complex jig units, etc., and it is compatible with parts of various specifications. It can save equipment cost. In addition, it is not necessary to separately provide equipment such as an inspection jig for inspecting a defect of the product.

In addition, in the related art, even if the initial vision unit (VU) and each robot are installed at the correct position by minimizing the distortion between the equipment by using a feeder or a laser leveler, the vision unit (VU) and each robot generate coordinate system distortions. Since the moving coordinates and the recognition coordinates of the vision unit VU are different, there is a problem that productivity is lowered by several corrections.

However, the robot assembly and control method for parts assembly according to an embodiment of the present invention by matching the vision coordinate system and the robot coordinate system through the first correction step (S1) described above, the robot controller RC each hanger in the work space on the vision coordinate system It is possible to accurately recognize the movement position of the robot (R1) (R2) (R3), and at the same time to accurately control the movement amount and rotation angle of the parts (P1, P2, P3) with the corrected coordinate values.

In addition, in the related art, when regulating and transferring parts through a hanger robot, a robot coordinate system was formed by setting the reference coordinate of the robot to a point on the robot and teaching the reference coordinate manually, but accordingly, a change occurred in the part If the same parts are not regulated, there is a problem that the detection and coordinate correction thereof are impossible and cause a welding defect due to a matching error between the parts.

However, the robot assembly and control method for parts assembly according to an embodiment of the present invention is a second correction robot coordinate system corrected based on the parts (P1, P2, P3) on the vision coordinate system through the second correction step (S3) It is possible to control each hanger robot (R1, R2, R3) through the component regulation error or forming tolerances or parts of the parts (P1, P2, P3) according to the repeating behavior of each hanger robot (R1, R2, R3) The occurrence of deformation error due to welding of P1, P2, P3) can be minimized. In addition, a deformation occurs in the parts P1, P2, and P3 regulated to each hanger H1, H2, and H3 of each hanger robot R1, R2, and R3 through the second correction robot coordinate system, or completely. Even if parts of the same shape are not regulated, accurate rotation coordinate values can be calculated, and correction of coordinate values is also easy.

In addition, conventionally, when moving the parts (P1, P2, P3) to be assembled to each other in the work space based on the model data coordinates (Mx, My, Mz) in the drawing program, between the parts (P1, P2, P3) There is a problem in that it is impossible to continuously produce a product of the same quality because the cause of the interference is not possible because of the quality of the parts, the scattering occurs during the robot transfer.

However, the robot assembly and control method for parts assembly according to an embodiment of the present invention, the camera 11 of the vision unit (VU) at a position spaced apart from each other by a predetermined distance in the work space matching the parts (P1, P2, P3) The interference between the parts P1, P2, and P3 may be predicted and determined in advance by using the position coordinate values recognized through the welding, so that the interference between the parts P1, P2 and P3 may be avoided by correcting the position of the parts.

Accordingly, it is possible to prevent deformation scattering caused by interference assembly due to interference between the parts P1, P2, and P3 and quality distribution of the assembled product, and it is possible to reduce the production cost of the jig by eliminating the production of a dedicated inspection jig.

Although one embodiment of the present invention has been described above, the present invention is not limited to the above embodiment, and is easily changed by those skilled in the art to which the present invention pertains. It includes all changes to the extent deemed acceptable.

VU: Vision Unit
R1, R2, R3: first, second, third hanger robot
R4: welding robot
VC: vision controller
RC: robot controller
11: camera
13: frame
13a: pillar beam
13b: upper beam
15: reference pin
21: monitor
31: alarm
41: connecting shaft
43: guide rail
45: screw shaft
51,53: descent slider
55: reducer
57: rotating plate
LR1, LR2: first and second linear rails
SR1, SR2: first and second slider
M1, M2: first and second motors
P1, P2, P3: first, second, third parts
T: Calibration Tool
H1, H2, H3: first, second, third hangers
W: welding machine
GB: gearbox

Claims (8)

In the control method of a robot system for assembly of parts comprising a vision unit having a camera, a plurality of hanger robots having each hanger, at least one welding robot having a welding machine, a vision controller, and a robot controller,
The correction value is calculated by comparing the 3-point position coordinates on the vision coordinate system and the corresponding 3-point position coordinates on the robot coordinate system generated by scanning the position of the correction tool on each hanger robot according to the minimum 3-point behavior of each hanger robot. A first correction step S1 of correcting the robot coordinate system to match the vision coordinate system with the robot coordinate system;
A part regulation step of controlling each hanger by gripping each part to be assembled through the hanger of each hanger robot (S2);
A first correction value calculated by calculating a coordinate difference value between the correction tool on each hanger robot and a component regulated on each hanger with a camera of a vision unit, and calculating the coordinate difference value between the correction tool and each position coordinate on the vision coordinate system of the part; A second correction step S3 of correcting the robot coordinate system corrected in the correction step and setting the robot coordinate system based on the component;
Control parts of the hanger robot to apply the distance coordinates to the other parts assembled to one of the parts that are matched for assembly, the parts to move the parts to a distance spaced apart from each other in the work space Step S4;
When the parts are spaced apart from each other in the work space by the camera of the vision unit, the vision controller generates respective position coordinates on the vision coordinate system of the parts, and compares the respective position coordinates and the spaced coordinate values together. Analyze and predict the interference between the parts to calculate a third correction value for the coordinate interference value of each position coordinate of the parts, wherein the position coordinates for the other one matching the one of the parts, A third correction step S5 of correcting a position by applying three correction values;
A part matching step (S6) of controlling the hanger robot for regulating the other part as a hanger and returning the other part to the one part by a spaced coordinate value in a workspace to match the parts together;
Welding step (S7) for welding the weld of the matched parts by controlling the at least one welding robot and the welding machine; And
An inspection step (S8) of performing a defect inspection according to a tolerance range by comparing a position coordinate on a vision coordinate system generated by scanning a product welded on the welded parts of the parts with the camera by model data coordinates on a model coordinate system;
Control method of a robot system for assembly of parts comprising a. The method of claim 1,
The first correction step (S1) is
Scanning the vertices of the calibration tool on each hanger robot according to the minimum three-point behavior of each hanger robot on the work space through the camera of the vision unit, the vision controller coordinates the 3-point position on the vision coordinate system with respect to the vertex of the calibration tool. Generates a first correction value for the coordinate difference value by comparing the three-point position coordinates on the robot coordinate system with respect to the vertex of the correction tool received from the robot controller and the three-point position coordinates on the vision coordinate system; And applying the first correction value to the robot coordinate system set in the robot controller to correct and set the first correction robot coordinate system. The method of claim 2,
The first correction step (S1) is
The robot controller controlling each hanger robot to move three points to an arbitrary three point position on the work space (S11);
Outputting image information by scanning a vertex of a correction tool fixed to an arm tip of each hanger robot with respect to an arbitrary 3-point position according to the 3-point behavior of each hanger robot through the camera of the vision unit (S12);
Analyzing image information of the correction tool for any three-point position of each hanger robot to generate first, second and third position coordinates on a vision coordinate system for a vertex of the correction tool (S13);
Receiving (S14) first, second and third position coordinates on the robot coordinate system for the vertex of the correction tool at any three point positions of the hanger robots;
Calculating a first correction value for the coordinate difference values between the first, second, and third position coordinates on the robot coordinate system and the first, second, and third position coordinates on the vision coordinate system (S15); And
Transmitting the first correction value to the robot controller and correcting and setting the robot coordinate system with the first correction robot coordinate system (S16);
Control method of a robot system for assembly of parts comprising a. The method of claim 1,
The second correction step S3 is
The vision controller scans the vertex of the calibration tool on each hanger robot and any point on the regulated part on each hanger in the workspace by means of the camera of the vision unit, and the vision controller verifies the vertex of the calibration tool and any on the part. Generating respective position coordinates on the vision coordinate system for one point of the second position, calculating a second correction value for the coordinate difference value of each position coordinate, and adding the second correction value to the robot coordinate system corrected by the robot controller in the first correction step. A method of controlling a robot system for assembly of parts, comprising applying a correction value and correcting and setting the second correction robot coordinate system again. The method of claim 4, wherein
The second correction robot coordinate system
And a coordinate system in which a reference coordinate for controlling each hanger robot is moved from a robot rotation center point (RRCP), which is a vertex of a correction tool, to a component rotation center point (PRCP), which is an arbitrary point on the part. The method of claim 4, wherein
The second correction step S3 is
Controlling, by the robot controller, each hanger robot to position a part regulated by each hanger on each hanger robot at a set position on a work space (S31);
Outputting image information by scanning a vertex of a correction tool fixed to an arm tip of each hanger robot on a work space and an arbitrary point of a part restricted to each hanger through a camera of the vision unit (S32);
Analyzing first image information of a vertex of the correction tool to generate a first position coordinate which becomes a robot rotation center point (RRCP) on a vision coordinate system (S33);
Analyzing the image information of any one point of the part and generating a second position coordinate which becomes a part rotation center point (PRCP) on a vision coordinate system (S34);
Calculating a second correction value for a coordinate difference value of the first and second position coordinates on the vision coordinate system (S35); And
Transmitting the second correction value to the robot controller and correcting and setting the robot coordinate system corrected in the first correction step with a second correction robot coordinate system (S36);
Control method of a robot system for assembly of parts comprising a. The method of claim 1,
The third correction step (S5)
A step in which one hanger robot places one part on the workspace with model data coordinates on the model coordinate system set in the drawing program (S51);
Positioning another part assembled by the other hanger robot on the work part by applying a spaced coordinate value of a predetermined distance from the model data coordinates set in the drawing program (S52);
Outputting image information by scanning mutual matching points for the one component and the other component through a camera of the vision unit;
Generating first and second position coordinates of each matching point in a state spaced apart on a vision coordinate system by analyzing image information about the one component and the other component (S54);
Comparing the first and second positional coordinates on a vision coordinate system with the spaced coordinate values to determine whether there is interference between the one component and the other component as coordinate interference values (S55);
Calculating a third correction value for the coordinate interference value when an interference occurs between the one component and the other component (S56); And
Sending the third correction value to the robot controller and applying the third correction value to a position coordinate on the robot coordinate system with respect to the other component to correct the position of the other component in the working space (S57);
Control method of a robot system for assembly of parts comprising a. The method of claim 7, wherein
The model data coordinates are
Robot component for assembly of parts comprising the coordinates of the part model, the positional coordinates of the reference pin as the reference coordinates by inserting the data of the reference pin that is the coordinate reference on the vision coordinate system into the model data on the drawing program of the component Control method.

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