JP2010076020A - Parts positioning method and parts positioning tool - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a parts positioning method for positioning parts to the predetermined position which is capable of obtaining the sufficient parts position keeping force and parts position accuracy without increasing the size of the constitution of a parts positioning device and complicating the constitution thereof. <P>SOLUTION: In the parts positioning method, a parts (a workpiece 1) to be positioned at the predetermined position is supported in a fixed state by a movable tool (a parts reference tool 20) which is movably provided in a predetermined range while being supported by a robot 10, and the workpiece 1 is positioned by moving the parts reference tool 20. A fixing tool (a supporting tool 30) is used, which is provided at the predetermined position in a fixed state, fitting parts (a positioning pin 25, a positioning hole part 35) for positioning the parts reference tool 20 with respect to the supporting tool 30 in a fitted state to each other with predetermined accuracy are provided on the parts reference tool 20 and the supporting tool 30, respectively, and the workpiece 1 is positioned with these fitting parts being fitted to each other. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a component positioning method and a component positioning jig for positioning a component at a predetermined position during operations such as welding, machining, and assembly of components.

  2. Description of the Related Art Conventionally, for example, in a manufacturing process of an automobile part or the like, a system in which work such as welding is performed in a state where the part is positioned at a predetermined position is used for parts welding, machining or assembly. Yes. In such a system, for example, a part subjected to processing such as welding by an automatic operation by a robot or the like is positioned at a predetermined position (see, for example, Patent Document 1).

  In Patent Document 1, as a configuration for positioning and fixing a part (workpiece) at a predetermined position in an assembly process or the like, positioning means and fixing means that are movable in a three-dimensional direction by a moving means including a plurality of arms and the like. The structure provided with these is disclosed. Here, the positioning means engages with a positioning portion provided on the workpiece to position the workpiece at a predetermined position, and the fixing means supports the workpiece with the fixing portion provided on the workpiece, and also holds the workpiece at a predetermined position. Secure to.

  Conventionally, the following configuration (hereinafter referred to as “conventional configuration”) is used as a configuration for positioning a component at a predetermined position in a manufacturing process of various types of components. That is, as shown in FIG. 9, in the conventional configuration, the workpiece 101 as a component to be positioned is positioned at a predetermined position while being supported by the robot 110. In other words, in the conventional configuration, the workpiece 101 supported and fixed at the tip of the robot 110 is transported to a predetermined position where the robot 110 is subjected to processing such as welding.

  Specifically, the workpiece 101 is supported by the robot 110 via the component reference jig 120. In FIG. 9, the workpiece 101 is a plate-like member having a predetermined shape. The robot 110 is configured as a so-called robot arm having a plurality of arms. A component reference jig 120 is provided at the tip of the robot 110. The component reference jig 120 can be moved freely (with a considerable degree of freedom) in the three-dimensional direction by the operation of the robot 110.

  The component reference jig 120 has a support surface 121 for supporting the workpiece 101. The component reference jig 120 is fixed to the support surface 121 in a state where the workpiece 101 is positioned. The support surface 121 is provided with a pin-shaped positioning protrusion 122 for positioning the workpiece 101 with respect to the component reference jig 120. In contrast, the workpiece 101 is provided with a hole 101a. That is, the workpiece 101 is positioned with respect to the component reference jig 120 on the support surface 121 by inserting the positioning protrusion 122 into the hole 101a. The workpiece 101 positioned on the support surface 121 is fixed to the component reference jig 120 by fixing means (not shown) such as a clamp mechanism.

  With such a configuration, the workpiece reference jig 120 is moved by the operation of the robot 110, so that the workpiece 101 fixed in a state of being positioned with respect to the component reference jig 120 is positioned at a predetermined position. . Here, the robot 110 uses a position reference such as a so-called tool center point (TCP) provided in the component reference jig 120, for example, so that the component reference jig 120 corresponds to a predetermined position where the workpiece 101 is positioned. Position to the position where you want to. Then, work such as welding is performed on the workpiece 101 positioned at a predetermined position by the stopped robot 110.

  According to such a conventional configuration, the component reference jig 120 can be disposed anywhere (with a high degree of freedom) within the movable range of the robot 110. That is, for example, when the predetermined position where the workpiece 101 is positioned differs depending on the type of parts, the plurality of different predetermined positions can be flexibly handled within the movable range of the robot 110. For this reason, high versatility can be obtained for equipment for positioning the workpiece 101 by the robot 110.

  By the way, regarding the positioning of the component with respect to the predetermined position, a force (component position holding force) for maintaining the state where the component is positioned is required. In other words, the component position holding force is a force that holds the position of the component against the force acting on the component when the positioned component is subjected to processing or the like. For example, when the positioned part is subjected to welding, the part position holding force is a force that opposes the force generated by the deformation of the part due to welding, and when the positioned part is subjected to machining, This is the force that opposes the force acting on the parts during machining.

  In addition, regarding positioning of a component with respect to a predetermined position, a considerable degree of accuracy (component position accuracy) is required according to the type of work performed on the positioned component. For example, when arc welding is performed on a component in a positioned state, the component position accuracy within an error range (variation) of about several hundred mm may be required.

  Regarding the component position holding force and the component position accuracy for positioning the component with respect to such a predetermined position, the conventional configuration as described above (see FIG. 9) has the following problems. That is, in the conventional configuration, the rigidity of the robot 110 with respect to the load acting on the position reference provided on the component reference jig 120 or the like as described above when the component position holding force is in the stopped state of the robot 110 (the positioning state of the workpiece 101). Depends on (support rigidity). That is, the workpiece 101 in the positioned state is supported only by the robot 110. For this reason, in the conventional configuration, the component position holding force is weak, and a sufficient component position holding force may not be obtained. In order to obtain a sufficient component position holding force in the conventional configuration, it is conceivable to increase the rigidity of the robot 110. However, increasing the rigidity of the robot 110 causes an increase in the size and complexity of the device configuration.

  In the conventional configuration, the component position accuracy depends on the repetition accuracy of the operation of the robot 110. That is, when the movement of the workpiece 101 between the plurality of different stop positions is repeatedly performed by the operation of the robot 110, the position accuracy with respect to each stop position varies within a predetermined error range. For this reason, in the conventional configuration, the component position accuracy is poor, and sufficient component position accuracy may not be obtained. Specifically, in the conventional configuration, the component position accuracy is within an error range of, for example, ± 0.2 mm or more.

As described above, the conventional configuration has problems in terms of component position holding force and component position accuracy. For this reason, the conventional configuration is not suitable for positioning a part that requires a large part position holding force or a part that requires high part position accuracy during work such as welding to the part.
JP-A-6-304788

  The present invention has been made in view of the problems as described above, and the problem to be solved is sufficient for positioning the component with respect to a predetermined position without causing an increase in size or complexity of the apparatus configuration. It is an object of the present invention to provide a component positioning method and a component positioning jig capable of obtaining a sufficient component position holding force and component position accuracy.

  The problems to be solved by the present invention are as described above. Next, means for solving the problems will be described.

  That is, according to the first aspect of the present invention, a part to be positioned with respect to a predetermined position is supported in a state of being supported by a robot and fixed to a moving jig provided to be movable within a predetermined range, and the moving treatment is performed. A part positioning method for positioning the part by moving a tool, wherein the moving jig is used by using a fixing jig provided in a fixed state with respect to the predetermined position where the part is positioned. In addition, each of the fixing jigs is provided with a fitting portion that positions the moving jig with respect to the fixing jig with a predetermined accuracy in a state of being fitted to each other, and the fitting portions are fitted to each other. The parts are positioned.

  In Claim 2, The said fitting part provided in the said movement jig among the said fitting parts, and the said fitting part provided in the said fitting part provided in the said fixing jig are made into the said some fitting part. A plurality is provided corresponding to a predetermined position.

  According to a third aspect of the present invention, a clamp mechanism is provided for fixing the moving jig to the fixing jig in a state where the fitting portions are fitted to the fixing jig.

  According to a fourth aspect of the present invention, there is provided a component positioning jig for positioning a component to be positioned with respect to a predetermined position, the component positioning jig being movably provided within a predetermined range while being supported by a robot. A moving jig for supporting the moving jig, and a fixing jig provided in a fixed state with respect to the predetermined position where the component is positioned by the movement of the moving jig. The fixture and the fixing jig have a fitting portion that positions the moving jig with respect to the fixing jig with a predetermined accuracy in a state of being fitted to each other. The parts are positioned.

  According to a fifth aspect of the present invention, at least one of the moving jig and the fixing jig has a plurality of the fitting portions corresponding to the plurality of the predetermined positions.

  According to a sixth aspect of the present invention, the fixing jig includes a clamp mechanism for fixing the moving jig to the fixing jig in a state where the fitting portions are fitted to each other.

As effects of the present invention, the following effects can be obtained.
That is, according to the present invention, it is possible to obtain sufficient component position holding force and component position accuracy without increasing the size and complexity of the device configuration for positioning the component with respect to a predetermined position.

  In the configuration in which the component to be positioned is positioned at a predetermined position while being supported by the robot, the present invention is fixed to a moving jig for supporting the component on the robot at a position different from the robot. The fixing jig provided in the state is provided, and the moving jig is positioned with respect to the fixing jig, thereby supporting the support of the parts by the robot and the positioning accuracy. Embodiments of the present invention will be described below.

  As shown in FIG. 1, in this embodiment, a workpiece 1 as a component to be positioned is positioned at a predetermined position while being supported by a robot 10. That is, the workpiece 1 supported and fixed at the tip of the robot 10 is moved to a predetermined position by the robot 10 and positioned.

  Here, the predetermined position at which the workpiece 1 is positioned (hereinafter referred to as “work reference position”) is, for example, welding of other parts to the workpiece 1 (arc welding or the like), machining on the workpiece 1, or workpiece 1 This is a position defined for the work 1 when a predetermined work is performed on the work 1 such as assembling other parts. That is, the workpiece 1 is positioned at the workpiece reference position by the operation of the robot 10 and is subjected to processing such as welding by an automatic operation by another robot (robot other than the robot 10), for example, while being supported by the robot 10.

  The workpiece 1 is supported by the robot 10 via the component reference jig 20. In the present embodiment, the workpiece 1 is a plate-like member having a predetermined shape. The component reference jig 20 is provided at the tip of the robot 10. The component reference jig 20 can be moved freely in the three-dimensional direction (with the same degree of freedom with the same degree of freedom) by the operation of the robot 10.

  The robot 10 is configured as a so-called robot arm (multi-joint robot) having a plurality of arms. In the present embodiment, the robot 10 includes a first arm 11, a second arm 12, and a third arm 13 as a plurality of arms from the base side to the tip side of the robot 10. The plurality of arms constitute an articulated robot, for example, by mutually connecting ends of the arms so as to be rotatable by a driving source such as a motor.

  In the robot 10, a robot arm portion having a first arm 11, a second arm 12, and a third arm 13 is supported by a base portion 10 a. That is, as shown in FIG. 1, the end of the robot arm on the base side (one end of the first arm 11) is connected to the base 10a. The base 10a is provided in a fixed state with respect to the floor surface 2 on which the robot 10 is disposed.

  The robot 10 of the present embodiment is configured as a flexible robot arm that can be posture-controlled at various positions and angles with the base 10a as a base point. In the robot 10, a component reference jig 20 is provided at the tip of the robot arm (the tip of the third arm 13). With this configuration, the component reference jig 20 can be freely moved in the three-dimensional direction by the operation of the robot 10.

  The component reference jig 20 has a support surface 21 for supporting the workpiece 1. The component reference jig 20 is fixed to the support surface 21 in a state where the workpiece 1 is positioned. The support surface 21 is provided with a positioning protrusion 22 for positioning the workpiece 1 with respect to the component reference jig 20. The positioning protrusion 22 is a pin-like portion that is formed to protrude from the support surface 21. A hole 1 a is provided in the work 1 with respect to the positioning protrusion 22. That is, the workpiece 1 is positioned with respect to the component reference jig 20 on the support surface 21 by inserting the positioning protrusion 22 into the hole 1a. The workpiece 1 positioned on the support surface 21 is fixed to the component reference jig 20 by fixing means (not shown) such as a clamp mechanism.

  The configuration for positioning and fixing the workpiece 1 with respect to the component reference jig 20 is not limited to this embodiment. When positioning and fixing the workpiece 1 with respect to the component reference jig 20, for example, a magnetic force by a magnet or a suction force by air suction is used instead of or in addition to the positioning protrusion 22 or the like as described above. Also good.

  The operation of the robot 10 is controlled based on a predetermined operation program. In controlling the operation of the robot 10, a so-called tool center point (TCP) is set as a position reference of the robot 10 (a reference point of a coordinate system set for the robot 10). The position where the TCP is set is not particularly limited, but in the present embodiment, the TCP is set, for example, at the base of the positioning protrusion 22 in the component reference jig 20 (see point C in FIG. 1). ). That is, the TCP is a reference position for the workpiece 1 that is supported and fixed in a state where the TCP is positioned with respect to the robot 10 via the component reference jig 20.

  By recognizing the TCP position set in this way, the operation of the robot 10 is controlled based on a predetermined operation program while recognizing the position (posture) of the robot 10. Here, the control of the operation of the robot 10 is performed based on teaching data or the like previously taught for the operation program of the robot 10. The position of the component reference jig 20 provided at the tip of the robot 10 is controlled by the operation of the robot 10 thus controlled, and the workpiece 1 fixed to the component reference jig 20 is moved relative to the workpiece reference position. Positioned.

  As described above, in the component positioning method according to the present embodiment, the workpiece 1 that is a positioning target with respect to the workpiece reference position is placed on the component reference jig 20 provided to be movable within a predetermined range while being supported by the robot 10. The workpiece 1 is positioned by supporting it in a fixed state and moving the component reference jig 20. That is, in the present embodiment, the component reference jig 20 is provided so as to be movable within a predetermined range while being supported by the robot 10, and functions as a moving jig that supports the workpiece 1 in a fixed state.

  In the present embodiment, the robot 10 functions as a moving unit that supports the component reference jig 20 and enables the component reference jig 20 to move within a predetermined range. Note that the configuration of the robot 10 is not limited to the present embodiment. As a robot that is a moving means for supporting and moving the component reference jig 20, a general industrial robot or the like can be used as long as it has a configuration that allows the component reference jig 20 to move freely in a three-dimensional direction. A known configuration is appropriately used.

  In the component positioning method according to the present embodiment, the workpiece 1 fixed to the component reference jig 20 that is moved by the operation of the robot 10 is fixed in a predetermined positional relationship with respect to the workpiece reference position where the workpiece 1 is positioned. A support jig 30 provided in the state is used. That is, in the present embodiment, the support jig 30 functions as a fixing jig provided in a state of being fixed with respect to the workpiece reference position by the movement of the component reference jig 20. That is, the support jig 30 is provided in a fixed state in relation to the workpiece reference position where the workpiece 1 is positioned via the component reference jig 20.

  As described above, the component positioning jig according to the present embodiment is for positioning the workpiece 1 with respect to the workpiece reference position, and includes the component reference jig 20 and the support jig 30.

  The component reference jig 20 has a base 23. In this embodiment, the base 23 has a substantially rectangular parallelepiped (thick plate) outer shape. The base portion 23 is connected to the robot 10 via the connecting portion 24. The base portion 23 is connected to the robot 10 by a connecting portion 24 from the plate surface side on one side (lower side in FIG. 1). The connecting portion 24 is provided at the distal end portion of the third arm 13. That is, the component reference jig 20 has a configuration in which the base portion 23 is supported by the connecting portion 24 provided at the tip portion of the third arm 13, so that the tip portion of the robot arm portion in the robot 10 (tip portion of the third arm 13). Is provided. Further, in the component reference jig 20, the support surface 21 for supporting the workpiece 1 is formed on the plate surface side on the other side of the base portion 23 (the side opposite to the connecting portion 24 side, the upper side in FIG. 1). Is done.

  In the component reference jig 20, the base 23 is supported so as to be rotatable with respect to the robot 10 with the direction substantially perpendicular to the plate surface (vertical direction in FIG. 1) as the rotation axis direction. That is, the robot 10 has a wrist axis that can rotate at the tip of the robot arm, and the base 23 is rotatably supported by the wrist axis. As described above, in this embodiment, the component reference jig 20 is provided so as to be able to be rotated by a predetermined rotation axis (a wrist axis of the robot 10) in addition to the movement by the operation of the robot 10.

  The support jig 30 includes a jig body 31 and a support portion 32 that supports the jig body 31. In the present embodiment, the jig body 31 has a substantially rectangular parallelepiped outer shape. The support portion 32 is a columnar portion that is erected on the floor surface 2, and supports the jig body 31 with respect to the floor surface 2.

  Further, the support jig 30 is provided in a state of being fixed with respect to the workpiece reference position by the movement of the component reference jig 20 as described above. That is, the workpiece reference position is determined by, for example, three-dimensional coordinates with respect to a predetermined position on the floor surface 2 in relation to the floor surface 2. Accordingly, in this case, the support jig 30 is provided in a fixed state in relation to the floor surface 2, thereby being in a fixed state in relation to the workpiece reference position. In other words, the support jig 30 is provided in a state where the relative position with respect to the workpiece reference position is constant.

  Therefore, in the present embodiment, in the support jig 30, the support portion 32 is provided in a state of being fixed to the floor surface 2, and the jig main body 31 is provided in a state of being fixed to the support portion 32. Thus, the support jig 30 is provided in a state of being fixed to the floor surface 2. On the other hand, the component reference jig 20 is provided so as to be freely movable in the three-dimensional direction by the robot 10 operating with the base 10a provided in a fixed state on the floor 2 as described above.

  Here, the support jig 30 provided in a fixed state with respect to the workpiece reference position has been described by taking the relationship with the floor surface 2 as an example, but the floor surface 2 is another one that defines the workpiece reference position. (Part) can be substituted. That is, the support jig 30 is provided in a state where the relative positional relationship with the workpiece reference position is constant (a state in which the support jig 30 is fixed in relation to the workpiece reference position).

  As described above, the jig of this embodiment is configured such that the movable component reference jig 20 is positioned with respect to the support jig 30 provided in a fixed state with respect to the workpiece reference position. Yes. This supports the support and positioning accuracy of the workpiece 1 positioned by the robot 10. Here, for the positioning of the component reference jig 20 with respect to the support jig 30, a partly fitting action of the component reference jig 20 and the support jig 30 is used.

  That is, in the component positioning method of the present embodiment, the component reference jig 20 is positioned with a predetermined accuracy with respect to the support jig 30 while being fitted to the component reference jig 20 and the support jig 30. A fitting portion is provided. Then, the workpiece 1 is positioned in a state where these fitting portions are fitted to each other.

  Specifically, as shown in FIGS. 1 to 3, the component reference jig 20 has a positioning pin 25 as a fitting portion for positioning the workpiece 1 (hereinafter referred to as “positioning fitting portion”). Have. The positioning pin 25 is provided in the component reference jig 20 so as to protrude in a direction substantially parallel to the support surface 21 from the side surface of the base portion 23. The positioning pin 25 is a rod-shaped part having a circular or polygonal cross-sectional shape. Thus, the positioning pin 25 provided in the component reference jig 20 is a portion that forms a fitting protrusion as a positioning fitting portion.

  The support jig 30 has a positioning hole 35 as a positioning fitting portion with respect to the positioning pin 25 of the component reference jig 20. The positioning hole 35 is a hole into which the positioning pin 25 is inserted. Therefore, the positioning hole 35 has a shape corresponding to the cross-sectional shape of the positioning pin 25. The positioning hole 35 is formed in the support jig 30 so as to open on one side surface of the jig body 31. Thus, the positioning hole portion 35 provided in the support jig 30 is a portion that forms a fitting recess as a positioning fitting portion.

  Then, the positioning pins 25 included in the component reference jig 20 are inserted into the positioning holes 35 formed in the support jig 30 so that the fitting portions included in each of the component reference jig 20 and the support jig 30 are included. That is, the positioning pins 25 and the positioning holes 35 (the jig main body 31) are fitted. Therefore, in this embodiment, the state in which the positioning pin 25 is inserted into the positioning hole 35 is a state in which the fitting portions of the component reference jig 20 and the support jig 30 are fitted.

  In the present embodiment, the fitting direction of the positioning pin 25 and the positioning hole 35, that is, the insertion direction of the positioning pin 25 with respect to the positioning hole 35 is a substantially horizontal direction (a direction substantially parallel to the floor surface 2). In other words, the positioning hole 35 of the jig body 31 is formed in a substantially horizontal direction (a direction substantially parallel to the floor surface 2). Therefore, in this embodiment, in the state where the positioning pin 25 protruding in the direction substantially parallel to the support surface 21 is inserted into the positioning hole 35 as described above, the support surface 21 that supports the workpiece 1 is substantially horizontal. (A direction substantially parallel to the floor 2).

  The positioning pins 25 and the positioning holes 35 position the component reference jig 20 with respect to the support jig 30 with a predetermined accuracy in a state of being fitted to each other. Here, the accuracy with respect to the positioning of the component reference jig 20 with respect to the support jig 30 (hereinafter referred to as “jig positioning”) is the diameter of the positioning hole 35 (hole diameter) and the diameter of the positioning pin 25 (pin diameter). And the difference (hole diameter−pin diameter). The predetermined accuracy for jig positioning is an error range that is sufficiently smaller than the error range (variation) of the position accuracy for the operation of the robot 10. Specifically, for example, when the error range of the position accuracy for the operation of the robot 10 is about ± 0.2 mm, the predetermined accuracy (hole diameter−pin diameter) for jig positioning is about 0.05 mm. Is set.

  The positioning pin 25 and the positioning hole 35 are fitted by the operation of the robot 10. That is, when the component reference jig 20 is moved by the robot 10, the positioning pin 25 is inserted into the positioning hole 35 of the jig main body 31 in a fixed state. In this manner, the workpiece 1 is positioned (positioning with respect to the workpiece reference position) in a state where the positioning pins 25 and the positioning holes 35 are fitted.

  Here, the fitting state between the positioning pin 25 and the positioning hole 35 corresponding to the positioning state of the workpiece 1 is, for example, a state where the tip of the positioning pin 25 is in contact with the bottom of the positioning hole 35 or the like. The state in which the insertion of the positioning pin 25 into the positioning hole 35 is completed by restricting the movement of the pin 25 in the insertion direction is used. And the operation | work, such as welding, is performed with respect to the workpiece | work 1 positioned by the workpiece | work reference position by being in the fitting state of the positioning pin 25 and the positioning hole part 35. FIG.

  Therefore, the positioning pin 25 and the positioning hole 35 are provided so that the workpiece 1 is positioned at the workpiece reference position (so that the TCP is positioned at a position corresponding to the workpiece reference position) in a state of being fitted to each other. That is, the position where the positioning pin 25 and the positioning hole 35 are provided, the shape and dimensions of the positioning pin 25, the depth of the positioning hole 35, and the like are designed according to the workpiece reference position.

  Here, the position of the component reference jig 20 in a state where the positioning pin 25 is inserted into the positioning hole 35 is appropriately set depending on the shape of the positioning pin 25, for example. Therefore, the positioning pin 25 is not limited to a straight line, and may be a rod-shaped portion that is bent, such as the right positioning pin 25 (25e) in FIG. Further, the position of the positioning hole 35 is appropriately set depending on the position where the positioning hole 35 is formed in the jig body 31, the height of the support portion 32 that supports the jig body 31, and the like.

  Further, when the positioning pin 25 is inserted into the positioning hole 35 by the operation of the robot 10, the tip of the positioning pin 25 has a shape that facilitates insertion into the positioning hole 35. Specifically, for example, as shown in FIG. 4, a tapered portion 25 t is formed at the distal end portion of the positioning pin 25. The tapered portion 25t is a tapered portion that decreases in diameter toward the distal end side of the positioning pin 25.

  As described above, since the taper portion 25t is formed in the positioning pin 25, when the positioning pin 25 is inserted into the positioning hole portion 35, a displacement of the positioning pin 25 with respect to the positioning hole portion 35 due to the operation of the robot 10 is allowed. , Easy to insert. The shape that facilitates insertion of the positioning pin 25 into the positioning hole 35 is not limited to a tapered shape such as the tapered portion 25t.

  Further, the positioning pin 25 and the positioning hole 35 are sufficiently fitted to each other so that sufficient support rigidity can be obtained with respect to the workpiece 1 in a state of being positioned at the workpiece reference position being subjected to processing or the like. , Shape (pin diameter, etc.), material, etc. are set. The material constituting the jig body 31 for forming the positioning pin 25 and the positioning hole 35 is not particularly limited. For example, the above-described support rigidity such as iron-based metal can be obtained. A tool that can be easily processed to obtain a predetermined accuracy for jig positioning is employed.

  As described above, in the component positioning jig of the present embodiment, the component reference jig 20 and the support jig 30 are connected to each other with respect to the support jig 30 in a predetermined state. As the fitting portion (positioning fitting portion) for positioning with accuracy, the positioning pin 25 and the positioning hole portion 35 are provided. The component positioning jig positions the workpiece 1 in a state where the positioning pins 25 and the positioning holes 35 are fitted.

  In the present embodiment, as for the positioning fitting portion, the fitting portion (positioning pin 25) provided on the component reference jig 20 side is a fitting protrusion, and the fitting portion provided on the support jig 30 side ( The positioning hole 35) is a fitting recess, but may be reversed. That is, as the positioning fitting portion, a fitting recess such as a positioning hole 35 is provided on the component reference jig 20 side, and a fitting projection such as a positioning pin 25 is provided on the support jig 30 side. Also good.

  That is, the fitting shape for the positioning fitting portion is not particularly limited. The fitting shape of the positioning fitting portion includes fitting of fitting portions provided in each of the component reference jig 20 and the support jig 30 by movement of the component reference jig 20 by the operation of the robot 10 and its fitting. Any shape can be used as long as it can provide a fitting action that can be released.

  Further, the fitting direction between the positioning pin 25 and the positioning hole 35 (the insertion direction of the positioning pin 25 with respect to the positioning hole 35) is not particularly limited. The fitting direction between the positioning pin 25 and the positioning hole 35 may be, for example, the downward direction in addition to the substantially horizontal direction as in the present embodiment.

  According to the component positioning method and the component positioning jig of the present embodiment as described above, a sufficient component position holding force can be obtained without positioning the workpiece 1 in size and complexity in positioning the workpiece 1 with respect to the workpiece reference position. It is possible to obtain (force for maintaining the position where the workpiece 1 is positioned) and component position accuracy (positioning accuracy of the workpiece 1 relative to the workpiece reference position).

  That is, in the configuration of the present embodiment, the component position holding force depends on the jig structure. That is, the component position holding force is the rigidity of the jig with respect to the load acting on the TCP set in the component reference jig 20, more specifically, the component reference jig in which the positioning pin 25 and the positioning hole 35 are fitted to each other. 20 and the rigidity of the support jig 30 (support rigidity). For this reason, in the configuration of the present embodiment, compared to the case where the component position holding force depends on the rigidity of the robot as in the conventional configuration, the component position holding force is strong and a sufficient component position holding force can be obtained.

  In the configuration of the present embodiment, the component position accuracy depends on the predetermined accuracy for jig positioning. That is, the component position accuracy depends on the difference (hole diameter−pin diameter) between the diameter of the positioning hole 35 (hole diameter) and the diameter of the positioning pin 25 (pin diameter). For this reason, in the configuration of this embodiment, compared with the case where the component position accuracy depends on the repeatability of the robot as in the conventional configuration, the component position accuracy is good and sufficient component position accuracy is obtained.

  As described above, the configuration of this embodiment has a strong component position holding force without adding to the size and complexity of the device configuration by adding a simple configuration jig to the conventional configuration, and the component position The positioning of the workpiece 1 with high accuracy is realized. Note that, according to the configuration of the present embodiment, for example, when a strong component position holding force or high component position accuracy is not required, the robot 10 is positioned alone (without using the support jig 30). It is also possible to perform.

  Moreover, in the component positioning method of this embodiment, among the positioning fitting portions, a plurality of positioning pins 25 that are fitting portions provided on the component reference jig 20 are provided corresponding to a plurality of workpiece reference positions. Yes. That is, in the component positioning jig of the present embodiment, the component reference jig 20 has a plurality of positioning pins 25 corresponding to a plurality of workpiece reference positions.

  In the present embodiment, as shown in FIGS. 2 and 3, four positioning pins 25 are provided in the component reference jig 20. Specifically, in the component reference jig 20, four positioning pins 25 are provided by providing one positioning pin 25 on each of the four side surfaces of the base portion 23. Therefore, as shown in FIG. 2, the four positioning pins 25 provided on the component reference jig 20 protrude in four directions.

  The four positioning pins 25 are provided so that the positions of the TCPs fitted to the jig body 31 are different from each other in each positioning pin 25. And the position of TCP in the state which each positioning pin 25 fitted to the jig | tool main body 31 respond | corresponds to four different workpiece | work reference positions, respectively. That is, for the four positioning pins 25, positions, shapes, and dimensions provided in the base 23 are set corresponding to four different workpiece reference positions. In other words, among the four positioning pins 25, the workpiece 1 is positioned with respect to four different workpiece reference positions by the positioning pins 25 used for fitting to the positioning holes 35.

  As described above, the plurality of positioning pins 25 provided in the component reference jig 20 are used as follows. Here, in order to distinguish the four positioning pins 25 included in the component reference jig 20, for convenience, as shown in FIGS. 5 and 6, for each of the four positioning pins 25, 25A, 25B, 25C, and 25D. The symbol is attached.

  FIG. 5 shows a state in which the positioning of the workpiece 1 with respect to the workpiece reference position is performed by using the positioning pin 25 </ b> B among the four positioning pins 25. That is, FIG. 5 shows a state in which jig positioning, that is, positioning of the workpiece 1 is performed by inserting the positioning pin 25B of the four positioning pins 25 into the positioning hole portion 35.

  On the other hand, FIG. 6 shows a state in which the positioning pin 25D provided on the side opposite to the positioning pin 25B (on the side surface on the opposite side of the base 23) among the four positioning pins 25 is used for positioning the workpiece 1. ing. That is, in this state, the positioning of the workpiece 1 is performed by inserting the positioning pin 25 </ b> D of the four positioning pins 25 into the positioning hole 35.

  The change of the positioning state from the positioning state by the positioning pin 25B (FIG. 5) to the positioning state by the positioning pin 25D (FIG. 6) is performed as follows. That is, in the positioning state by the positioning pin 25B shown in FIG. 5, the positioning pin 25B is pulled out from the positioning hole 35 by the operation of the robot 10. The position and posture of the base 23 are changed and the positioning pin 25D is positioned by the positioning hole 35 by the rotation of the base 23 by the wrist axis of the robot 10 and the operation of the robot arm of the robot 10 as described above. Plugged into. Here, since the positioning pin 25D is provided on the opposite side to the positioning pin 25B, the base 23 is rotated about 180 ° by the rotation of the wrist shaft of the robot 10.

  As described above, the positioning state is changed from the positioning state by the positioning pin 25B (FIG. 5) to the positioning state by the positioning pin 25D (FIG. 6). Move from C1 to point C2. That is, according to each of these positioning states, the workpiece 1 is positioned at the workpiece reference position corresponding to each TCP position (point C1, point C2). Similarly, by using the other positioning pins 25A and the positioning pins 25C, it is possible to correspond to different workpiece reference positions. 5 and 6, the work 1 is not shown for convenience.

  Thus, by providing a plurality of positioning pins 25 corresponding to a plurality of workpiece reference positions, it is possible to handle a plurality of workpiece reference positions with a single support jig 30. Thereby, the versatility with respect to several types of workpiece | work 1 improves. In the present embodiment, one support jig 30 can correspond to four workpiece reference positions. The plurality of workpiece reference positions are required, for example, when the workpiece 1 is an automobile part and the shape and dimensions of the parts corresponding to the workpiece 1 are different between different vehicle types.

  In the present embodiment, a configuration in which a plurality of positioning pins 25 are provided for one support jig 30 (positioning hole portion 35) is adopted as the configuration of the positioning fitting portion. A plurality of 30 sides may be provided. In this case, for example, an embodiment as shown in FIG.

  In FIG. 7, one positioning pin 25 is provided in the component reference jig 20, while the positioning hole 35, that is, the jig main body 31 that forms the positioning hole 35 in the support jig 30 is provided at three locations. The aspect in the case of being provided is shown. In this mode, the positioning hole 35A (the right support jig 30 in FIG. 7) is used as the positioning hole 35 into which the positioning pin 25 is inserted, and the positioning hole 35B (the upper support jig 30 in the same figure). ) And the case where the positioning hole 35C (the support jig 30 on the left side of the figure) is used, it is possible to correspond to different workpiece reference positions.

  Moreover, as a structure of a positioning fitting part, the structure in which all of the positioning pin 25 and the positioning hole part 35 are provided may be sufficient. That is, in the component positioning method of the present embodiment, among the positioning fitting portions, the positioning pins 25 that are fitting portions provided in the component reference jig 20 and the positioning portions that are fitting portions provided in the support jig 30. A plurality of fitting portions at least one of the hole portions 35 are provided corresponding to a plurality of workpiece reference positions. That is, in the component positioning jig of this embodiment, at least one of the component reference jig 20 and the support jig 30 has a plurality of positioning pins 25 or positioning holes 35 corresponding to a plurality of workpiece reference positions. .

  Here, when a plurality of positioning fitting portions are provided, in this embodiment, for example, a plurality of positioning pins 25 are provided on one side surface of the base portion 23, or a plurality of positioning hole portions are provided in the integrated jig body 31. 35 may be formed. However, the plurality of fitting portions are provided so that the fitting state by each fitting portion does not interfere with other fitting portions.

  As described above, by providing a plurality of positioning fitting portions at arbitrary positions, it is possible to arbitrarily correspond to a plurality of workpiece reference positions while utilizing the flexible operation of the robot 10.

  In the positioning configuration of the present embodiment, the following configuration is preferably provided. That is, a clamp mechanism for fixing the component reference jig 20 to the support jig 30 in a state where the positioning pins 25 and the positioning hole portions 35 are fitted to the support jig 30 is provided. Specifically, as shown in FIG. 8, in the present embodiment, as the clamp mechanism 40, a configuration including a clamp part 41 and a cylinder mechanism part 42 that operates the clamp part 41 is provided.

  The clamp portion 41 is provided in the support jig 30 so as to be rotatable with respect to one side surface (lower side surface in the present embodiment) of the jig main body 31. The clamp portion 41 has a substantially L-shape when viewed in the direction of the rotation axis shown in FIG. 8, and one end portion of the substantially L-shape is rotated with respect to the jig body 31 by the shaft support portion 41b. Supported as possible.

  The clamp portion 41 is engaged with the positioning pin 25 in a state of being inserted into the positioning hole portion 35 (hereinafter referred to as “inserted state”), whereby the positioning pin 25 in the inserted state is engaged with the jig body 31. Secure (clamp). For this reason, the positioning pin 25 has a locking portion 26 for receiving engagement by the clamp portion 41. The locking part 26 is a part that protrudes from the outer peripheral surface of the rod-shaped positioning pin 25.

  That is, the clamp portion 41 engages with the locking portion 26 of the positioning pin 25 to fix the inserted positioning pin 25 to the jig body 31. Here, the clamp part 41 has a locking surface 41 a for the locking part 26, and the locking part 26 has a locking surface 26 a for the clamp part 41. The clamp portion 41 is engaged with the locking portion 26 by rotating the clamp portion 41 with the shaft support portion 41b as a fulcrum, so that the locking surface 41a of the clamp portion 41 is locked with the locking surface 26a of the locking portion 26. This is done by contact engagement with. That is, the locking surface 41a of the clamp part 41 and the locking surface 26a of the locking part 26 are fixed to the jig body 31 of the positioning pin 25 in the inserted state by the rotation of the clamping part 41. 26a is performed.

  Thus, in the clamp mechanism 40, the clamp part 41 engages with the engaging part 26 of the positioning pin 25 in the inserted state by rotating the clamp part 41 about the shaft support part 41b. In this engaged state, the positioning pin 25 in the inserted state is sandwiched between the jig body 31 and the clamp part 41 via the locking part 26, thereby being fixed to the jig body 31 ( (Refer FIG.8 (b)).

  The clamp part 41 is rotated by the cylinder mechanism part 42. The cylinder mechanism portion 42 includes a cylinder portion 43 and a rod portion 44 that is provided so that a part of the cylinder mechanism portion 43 can protrude and retract. That is, the cylinder mechanism part 42 expands and contracts by the reciprocating movement of the rod part 44 relative to the cylinder part 43. The cylinder mechanism unit 42 is configured as, for example, a hydraulic cylinder or an air cylinder.

  The expansion / contraction operation of the cylinder mechanism unit 42 is used for the rotation operation of the clamp unit 41. That is, the distal end portion of the rod portion 44 is coupled to the clamp portion 41 via the coupling portion 44a. The connecting portion 44 a connects the rod portion 44 to the clamp portion 41 so that the expansion / contraction operation of the cylinder mechanism portion 42 (reciprocating movement of the rod portion 44) is transmitted as the rotation operation of the clamp portion 41. The cylinder portion 43 is provided in a state of being fixed to the jig body 31 via a support portion (not shown).

  In the configuration including the clamp mechanism 40 as described above, first, as shown in FIG. 8A, the positioning pin 25 is inserted into the positioning hole 35 by the operation of the robot 10 (see FIG. 1) (see arrow X1). ), The workpiece 1 is positioned. After such positioning, as shown in FIG. 8 (b), the clamp portion 41 engages with the locking portion 26 with the shaft support portion 41b as a fulcrum by the operation (extension operation) of the cylinder mechanism portion 42. Is rotated in the direction (see arrow X2). Then, the clamp portion 41 is engaged with the locking portion 26 via the locking surfaces 41 a and 26 a, so that the inserted positioning pin 25 is fixed to the jig body 31.

  On the other hand, when the positioning pin 25 is pulled out from the positioning hole 35, the operation of the cylinder mechanism portion 42 (contraction operation) rotates the clamp portion 41 in the direction opposite to the direction in which the locking portion 26 is engaged. The engagement of the clamp part 41 with the locking part 26 is released. Thus, in this configuration, the fixed state of the positioning pin 25 in the inserted state by the clamp part 41 and the released state thereof are operated by the expansion and contraction operation of the cylinder mechanism part 42.

  In the present embodiment, the cylinder mechanism portion 42 is used as a configuration for operating the clamp portion 41, but is not limited to this. In other words, the configuration for operating the clamp unit 41 may be a configuration using a drive source such as a motor.

  Thus, in the component positioning jig of the present embodiment, as a preferable configuration, the support jig 30 supports the component reference jig 20 with the positioning pins 25 and the positioning hole portions 35 fitted to each other. A clamp mechanism 40 for fixing to the tool 30 is provided.

  In the configuration of the present embodiment, by providing the clamp mechanism 40, it is possible to improve the holding force against the force in the direction in which the positioning pin 25 tends to come out of the positioning hole 35. As a result, the fitting direction of the positioning pin 25 and the positioning hole portion 35 (the insertion direction of the positioning pin 25 with respect to the positioning hole portion 35) can be easily accommodated in various directions (for example, upward).

The figure which shows the structure of the jig | tool for component positioning which concerns on one Embodiment of this invention. FIG. Similarly side view. The elements on larger scale which show the front-end | tip part of a positioning pin. The figure which shows an example of a component positioning state. (A) is a top view. (B) is a side view. The figure which shows another example similarly. The figure which shows another aspect about a jig | tool structure. The figure which shows an example of a structure of a clamp mechanism. The figure which shows the conventional positioning structure.

Explanation of symbols

1 Workpiece (parts)
10 Robot 20 Parts reference jig (moving jig)
25 Positioning pin (fitting part)
30 Support jig (fixing jig)
31 Jig body 35 Positioning hole (fitting part)
40 Clamp mechanism

Claims (6)

By supporting a component that is a positioning target with respect to a predetermined position in a state where it is supported by a robot and fixed to a moving jig that is movable within a predetermined range, and moving the moving jig, A component positioning method for positioning a component,
Using a fixing jig provided in a fixed state with respect to the predetermined position where the component is positioned,
Each of the moving jig and the fixing jig is provided with a fitting portion that positions the moving jig with respect to the fixing jig with a predetermined accuracy in a state of being fitted to each other.
A component positioning method comprising positioning the component in a state in which the fitting portions are fitted to each other.   Among the fitting portions, at least one fitting portion of the fitting portion provided in the moving jig and the fitting portion provided in the fixing jig is caused to correspond to a plurality of the predetermined positions. The component positioning method according to claim 1, wherein a plurality of components are provided.   The clamp mechanism for fixing the said moving jig to the said fixing jig in the state which the said fitting parts fitted in the said fixing jig is provided. The Claim 1 or Claim 2 characterized by the above-mentioned. Part positioning method. A component positioning jig for positioning a component to be positioned with respect to a predetermined position,
A moving jig that is movably provided within a predetermined range while being supported by the robot, and that supports the component in a fixed state;
A fixing jig provided in a state of being fixed to the predetermined position where the component is positioned by the movement of the moving jig,
The moving jig and the fixing jig have a fitting portion for positioning the moving jig with respect to the fixing jig with a predetermined accuracy in a state of being fitted to each other,
A component positioning jig for positioning the component in a state in which the fitting portions are fitted to each other. At least one of the moving jig and the fixing jig is
A plurality of the fitting portions corresponding to a plurality of the predetermined positions,
The component positioning jig according to claim 4. The fixing jig is
In a state where the fitting portions are fitted with each other, a clamp mechanism for fixing the moving jig to the fixing jig is provided.
6. The component positioning jig according to claim 4, wherein the component positioning jig is used.

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