JP2015009253A - Weld bolt inspection unit and weld bolt inspection device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a weld bolt inspection unit and a weld bolt inspection device that enable the weld inspection of a weld bolt to be carried out with high precision and constantly maintain a normal inspection system.SOLUTION: A weld bolt inspection unit according to the present invention, which is a weld bolt inspection unit that sequentially executes automatic inspections of the presence or absence and the weld strength of a plurality of weld bolts fitted to the arm tip of a robot and welded at a predetermined part of a workpiece, comprises a presence sensor that can detect the presence or absence of the weld bolts, a pressing part that presses the weld bolts, and a cylinder mechanism that advances and retreats the pressing part, where the pressing part is characterized by having a pressing tip arranged at a radially shifted position of the cylinder mechanism with respect to the axis position of the cylinder mechanism and by pressing the weld bolts with the pressing tip from the radial direction of the weld bolts to inspect the weld strength.

Description

  The present invention relates to a weld bolt inspection unit and a weld bolt inspection apparatus.

  Conventionally, for example, some structural parts such as automobiles are welded with a plurality of bolts necessary for fastening and fixing to other parts. In general, the welding bolt welded to the component is automatically welded to a predetermined position by a robot. Even in such an automated process, the inspection process for judging the mounting position of the welding bolt and the quality of the welding (appearance and strength) used visual confirmation by the operator and an inspection instrument (percussion hammer). It was done manually. For this reason, there has been a problem in quality variations, productivity, and the like due to inspection accuracy differing depending on the skill level of the operator.

  In order to improve such a situation, for example, a technique described in Patent Document 1 is disclosed. This technique automates the strength inspection for a welding bolt that has been conventionally performed by an operator. Specifically, the operation of hitting the welding bolt with a predetermined force by a hammer for hammering is mechanically performed by using the expansion and contraction operation of the piston rod of the air cylinder. This has made it possible to achieve a certain improvement in productivity.

Japanese Patent No. 2783062

  However, the welding inspection apparatus disclosed in Patent Document 1 performs only the inspection of the welding strength, and the inspection of the presence or absence of the welding bolt is first performed by a separate inspection apparatus. And the processing time for the inspection also increases.

  Moreover, in the inspection of the welding strength, it is determined whether or not the weld bolt has been removed as a result of the inspection, but the determination is made by detecting the movement amount of the piston rod, such as a limit switch attached to the air cylinder. Is going. Therefore, even if the welding bolt is welded in a state of being deviated from the specified position, the inspection is performed regardless of the position deviation of the welding bolt. In this case, if the moving amount of the piston rod is within the range indicating the presence of the weld bolt and the weld bolt is present without dropping off, the inspection passes even if the position of the weld bolt is shifted. Therefore, it is impossible to accurately detect the displacement of the welding bolt.

  Moreover, according to the welding inspection apparatus of patent document 1, since the several inspection mechanism provided with the air cylinder etc. is arrange | positioned in each location corresponding to several welding bolts, the position of a welding bolt differs. It is not possible to flexibly respond to varieties.

  Furthermore, for workpieces with multiple weld bolts, the components such as the linear motion cylinder will interfere with other weld bolts when pressing the weld bolt to be inspected. Depending on the formation position of the weld bolts above, some of them cannot be inspected.

  The pressing force applied to the welding bolt is set by adjusting the pressure of the air supplied to the air cylinder with a regulator. For this reason, for example, if an air leak occurs due to damage to the air cylinder, or if the contact portion of the inspection pressing member connected to the tip of the piston rod is deformed or dropped, an accurate pressing force is applied to the welding bolt. May not be possible. In such a case, there is a situation in which an accurate inspection is not performed, or a part with a suspected quality abnormality that has been damaged in a welded bolt is delivered to the next process as a non-defective product. There is a possibility of mass production.

  The present invention has been made in view of the circumstances as described above, and makes it possible to perform a weld inspection of a weld bolt with high accuracy and to maintain a normal inspection system and a weld bolt inspection unit. It is to provide a bolt inspection device.

  In order to achieve the above object, the present invention provides the following.

  The invention according to claim 1 is a welding bolt inspection unit that sequentially and automatically inspects the presence and absence of a plurality of welding bolts attached to a robot arm tip and welded to a predetermined portion of a workpiece, and the welding strength, A seating sensor capable of detecting the presence or absence of a welding bolt; a pressing portion that presses the welding bolt; and a cylinder mechanism that advances and retracts the pressing portion; and the pressing portion is relative to an axial position of the cylinder mechanism. It has a pressing tip disposed at a position displaced in the radial direction of the cylinder mechanism, and the welding strength is inspected by pressing the welding bolt from the radial direction of the welding bolt with the pressing tip. Welding bolt inspection unit.

  In the invention which concerns on Claim 2, it has a pressing tip detection sensor which can detect the position of the said pressing tip in the position which moved beyond the position of the said welding bolt, The welding bolt test | inspection of Claim 1 characterized by the above-mentioned. unit.

  The invention according to claim 3 is characterized in that the cylinder mechanism and the pressing portion are provided as a pair of symmetrical structures so as to face each other in the axial direction of the cylinder mechanism via the presence sensor. The welding bolt inspection unit according to claim 1 or 2.

  In the invention which concerns on Claim 4, it is a welding bolt test | inspection apparatus provided with the weld bolt test | inspection unit of any one of Claims 1-3, Comprising: The said weld bolt test | inspection unit is connected and made movable. A plurality of welds each having a robot and an inspection table on which the workpiece can be placed, wherein the welding bolt inspection unit is moved by the robot and welded to predetermined positions of the workpiece placed on the inspection table A welding bolt inspection device that automatically and sequentially inspects the presence of bolts and the welding strength.

  In the invention which concerns on Claim 5, the pseudo | simulation test | inspection part for confirming the operation | movement of the said welding bolt test | inspection unit pseudo was provided, The welding bolt test | inspection apparatus of Claim 4 characterized by the above-mentioned.

  According to the welding bolt inspection unit and the welding bolt inspection device according to the present invention, it is possible to perform the welding inspection on the welding bolt with high accuracy and always maintain a normal inspection system.

1 is an external view of a welding bolt inspection apparatus according to an embodiment of the present invention. It is a figure which shows (a) stud bolt and (b) weld bolt. It is a perspective view of the welding bolt inspection unit concerning one embodiment of the present invention. It is a top view of the welding bolt inspection unit concerning one embodiment of the present invention. It is a front view of the welding bolt inspection unit concerning one embodiment of the present invention. It is the schematic explaining the conditions, such as a strength test | inspection with respect to a welding bolt. It is the schematic explaining the conditions, such as a strength test | inspection with respect to a welding bolt. It is a perspective view of the welding bolt inspection unit concerning one embodiment of the present invention. It is the schematic which shows the relationship between a some welding bolt and a welding bolt test | inspection unit. It is a figure which shows the flow of a process of the usage example of the welding bolt test | inspection apparatus which concerns on one Embodiment of this invention.

  The gist of the present invention is that it is possible to automatically inspect the presence / absence, misalignment, and welding strength of a plurality of welding bolts welded to a predetermined portion of a workpiece in order, and improve inspection accuracy and a normal inspection system. It is intended to maintain.

  Hereinafter, an embodiment of a weld bolt inspection apparatus 1 including a weld bolt inspection unit 2 according to the present invention will be described with reference to the drawings. The front-rear and left-right relations in the weld bolt inspection unit 2 in this description are as follows. In FIG. 5, the rear side in the direction orthogonal to the paper surface is the rear side, the front side is the front side, and To do.

  In this description, the same or symmetrical structures and parts are attached with the same reference numerals in principle, only one of the left and right is described, and the description of the other is omitted as appropriate.

[Embodiment]
As shown in FIG. 1, the welding bolt inspection apparatus 1 includes a welding bolt inspection unit 2, a robot 3, an inspection table 4, and a pseudo inspection unit 5. The welding bolt inspection unit 2 is attached to the tip of an arm of the robot 3 and is seated with respect to a plurality of welding bolts 102 welded to a predetermined portion of the workpiece 101 set on the inspection table 4 on which the workpiece 101 can be placed. (It exists in a predetermined part), and it is comprised so that a positional offset test | inspection and a press test | inspection can be performed sequentially. In other words, the welding bolt inspection unit 2 is for automatically inspecting the presence / absence, misalignment, and welding strength of the plurality of welding bolts 102 welded to the workpiece 101 sequentially. The pseudo-inspection unit 5 periodically checks the operation of each part of the weld bolt inspection unit 2 and is intended to improve inspection accuracy.

  The welding bolt inspection unit 2 is configured to be able to apply a predetermined pressing force to the welding bolt 102 to be inspected and to detect the presence or absence of the welding bolt 102. The welding bolt inspection unit 2 automatically inspects the welding strength of the welding bolt 102 with respect to the workpiece 101, the presence of the welding bolt 102, and the positional deviation.

  A workpiece 101, which is an object to be inspected in the present embodiment, is a member for separating and partitioning a driver's seat side and an engine room side of an automobile, has a substantially plate shape and a substantially rectangular shape in plan view, and has a predetermined bending process. It has been applied. A plurality of welding bolts 102 are fixed to a predetermined surface of the workpiece 101 by welding, and various components such as electrical components are fastened and fixed to the workpiece 101 by the welding bolt 102.

  Moreover, the welding bolt test | inspection apparatus 1 of this embodiment makes 2 types of weld bolts 102 a test object. Specifically, as shown in FIG. 2A, the welding bolt inspection apparatus 1 includes a stud bolt 102A joined to the surface of the workpiece 101 (surface 104 to be inspected) by arc welding, and FIG. As shown in the figure, two types of weld bolts 102 </ b> B that are inserted into the bolt holes 103 formed in the workpiece 101 and joined to the workpiece 101 by resistance welding are set as inspection targets. Regardless of the type of bolt, the welding bolt 102 welded to the workpiece 101 is erected in a substantially vertical direction with respect to the inspection object surface 104 with the bolt head side as the base side with respect to the workpiece 101. Become. In other words, the welding bolt 102 is in a state of protruding in a substantially vertical direction with respect to the inspection target surface 104 of the workpiece 101 with the tip end side of the screw portion as the protruding end side.

  As shown in FIG. 1, the workpiece 101 is placed on the inspection table 4 by a separate robot (not shown) with the inspection target surface 104 to which the welding bolt 102 is welded facing substantially upward. The inspection table 4 is configured to support the workpiece 101 in a state where the workpiece 101 is positioned at a predetermined position in a predetermined posture. On the inspection table 4, the workpiece 101 is supported in a substantially fixed state so that the movement of the workpiece 101 is minimized even during the inspection by the welding bolt inspection apparatus 1.

  The inspection table 4 includes a plurality of workpiece detection sensors (not shown) and is configured to detect whether or not the workpiece 101 is placed at a predetermined position on the inspection table 4. The work detection sensor provided on the inspection table 4 is appropriately selected as long as it is a sensor that can detect the presence or absence of the work 101, such as a micro switch that operates by contact with the work 101 or a non-contact photoelectric sensor. Can be used.

  The robot 3 is connected to the welding bolt inspection unit 2 to be movable. That is, the robot 3 supports the welding bolt inspection unit 2 at its tip, and moves the welding bolt inspection unit 2 to an arbitrary place by an operation such as joint movement. The robot 3 includes a base 6, a first rotation unit 7, a first arm 9, a second arm 10, and a hand unit 11. The base 6 is a portion constituting the base end portion of the robot 3, has a substantially cylindrical outer shape, and is fixed on a predetermined installation surface with the cylinder axis direction as the vertical direction and supports the main body portion of the robot 3. .

  The first rotation unit 7 is provided on the base 6 and allows the main body of the robot 3 to rotate. The first rotation part 7 has a substantially cylindrical outer shape, is arranged concentrically with the base 6 with the cylinder axis direction as the vertical direction, and is provided with the cylinder axis direction as the rotation axis direction. The first arm 9 is pivotally connected to the first rotation portion 7 via a first pivot shaft 8 provided at the upper end portion of the first rotation portion 7. The second arm 10 is pivotally connected to the first arm 9 via a second pivot shaft (not shown) provided near the tip of the first arm 9. The hand portion 11 is pivotally connected to the second arm 10 via a third pivot shaft (not shown) provided near the tip of the second arm 10. The hand portion 11 has a substantially cylindrical portion as a portion protruding from the distal end side of the second arm 10, and a welding bolt inspection unit 2 is fastened by a bolt (not shown) to the distal end of the substantially cylindrical portion. Fixed.

  The first pivot shaft 8, the second pivot shaft, and the third pivot shaft that pivotally connect the respective portions in the main body portion of the robot 3 have a rotation axis direction set to a predetermined horizontal direction substantially parallel to each other. In addition, a second rotating portion 12 that is rotatable with the substantially vertical direction as a rotation axis direction is provided integrally with the hand portion 11 at the distal end portion of the hand portion 11 connected to the welding bolt inspection unit 2. . That is, the second rotating part 12 is a part that constitutes an end part on the protruding side of a substantially cylindrical part that is a protruding part from the second arm 10 of the hand part 11. The front end portion of the hand portion 11 is configured to be partially rotatable.

  Moreover, the 1st rotation part 7, the 1st arm 9, the 2nd arm 10, the hand part 11, and the 2nd rotation part 12 are each by a separate motor (not shown) and a hydraulic mechanism (not shown). , Can be rotated and tilted. Therefore, the robot 3 is positioned at an arbitrary position three-dimensionally within a predetermined circumferential range in which the hand unit 11 has a radius that is the maximum distance to the axial direction (vertical direction) of the first rotating unit 7 in a top view. It is configured to be able to move.

  The configuration of the robot 3 is not limited to the present embodiment, and various configurations can be used within the scope of the gist of the present invention.

  By connecting the welding bolt inspection unit 2 to the tip of the hand portion 11 of the robot 3 configured as described above, inspection of the plurality of welding bolts 102 disposed on the workpiece 101 is performed. The welding bolt 102 is inspected by the welding bolt inspection unit 2 with respect to the welding bolt 102 in a state in which the welding bolt inspection unit 2 is erected with respect to the inspection target surface 104 of the workpiece 101 as described above. The axial direction of the hand portion 11 and the protruding direction from the second arm 10 of the hand portion 11 (the rotation axis direction of the second rotation portion 12) are close to each other.

  When the welding bolt 102 is inspected, the welding bolt inspection unit 2 is described later on the axial extension of the welding bolt 102 (upward in FIG. 5) with respect to the welding bolt 102 as shown in FIGS. The seating sensor 23 is positioned at a predetermined distance and positioned so as to surround the welding bolt 102 between the left and right pressing tips 40. In the state where the weld bolt inspection unit 2 is positioned with respect to the weld bolt 102 in this manner, the presence sensor 23 detects the presence or absence of the weld bolt 102 or the presence or absence of the inclination with respect to the inspection target surface 104, and the pressing tip 40. Presses the welding bolt 102 from the lateral side to inspect whether the welding bolt 102 has a predetermined welding strength.

  The details of the pseudo-inspection unit 5 will be described later.

  Next, each part of the welding bolt inspection unit 2 will be described in detail. In the following, for the sake of convenience, the central axis direction of the substantially cylindrical portion that is the protruding portion from the second arm 10 of the hand portion 11 constituting the tip portion of the robot 3, that is, the first portion constituting the tip portion of the hand portion 11. The rotation axis direction of the second rotation unit 12 (hereinafter referred to as “hand unit axis direction”) will be described as the vertical direction (vertical direction).

  As shown in FIGS. 3, 4, and 5, the weld bolt inspection unit 2 mainly includes a main body portion 15 and an urging mechanism portion 16. The main body 15 includes a base plate 18 having a substantially rectangular plate shape. The base plate 18 is fixedly supported with respect to the hand portion 11 such that the plate surface thereof is substantially perpendicular to the hand portion axial direction. That is, the base plate 18 is fixedly supported by the hand unit 11 in a state where the upper plate surface thereof is in contact with the lower surface side of the second rotating unit 12 at the tip of the hand unit 11. The base plate 18 has an end portion on one side in the longitudinal direction (left-right direction in FIG. 4) in the substantially rectangular plate-like outer shape as a connecting portion 17 connected to the arm tip of the robot 3, that is, the hand portion 11.

  The connection part 17 is a part which enlarges the width dimension (dimension of a transversal direction) of the base plate 18 of a substantially rectangular plate shape with respect to other parts (see FIG. 4). The connecting portion 17 is formed with four bolt holes 19 penetrating the base plate 18, and the bolt holes 19 are used to contact the lower surface side of the arm tip of the robot 3 with the upper surface side of the base plate 18. In this state, the hand portion 11 and the base plate 18 are fastened and fixed to each other by a bolt (not shown). In this manner, the urging mechanism portion 16 is provided below the base plate 18 fixed to the hand portion 11 by the connecting portion 17.

  On the lower surface of the base plate 18, two support plates 20, 20 are suspended so as to surround an urging mechanism portion 16, which will be described later, from both sides in the longitudinal direction (left-right direction) of the base plate 18. Specifically, one support plate 20 is provided at an end portion of the base plate 18 opposite to the connection portion 17 side, and the other support plate 20 is other than the connection portion 17 and the connection portion 17 in the base plate 18. It is provided at the boundary with the main body. The two support plates 20 and 20 are each a rectangular plate-like member having substantially the same width as the main body portion of the base plate 18, with the longitudinal direction being the vertical direction and the plate surfaces facing each other in the left-right direction. Thus, the base plate 18 is suspended below. Each support plate 20 is fastened and fixed to the base plate 18 by two bolts 21 penetrating the base plate 18 from above the base plate 18.

  A seat sensor 23 for detecting the presence or absence of the welding bolt 102 is provided via a seat sensor bracket 22 below a substantially central portion in the left-right direction of the main body portion of the base plate 18. The occupancy sensor bracket 22 has a substantially rectangular plate-like outer shape, and is suspended from the base plate 18 with its plate surface facing in the front-rear direction and its upper end fixed to the rear side surface of the base plate 18. . A seat sensor 23 is disposed at the lower end of the seat sensor bracket 22.

  Specifically, a plate-like support piece is provided at the lower end portion of the seated sensor bracket 22 so as to face the plate surface in the left-right direction from one side in the left-right direction (left side in FIG. 5) and to protrude to the front side. The seating sensor 23 is provided inside the support piece (on the right side in FIG. 5) in a state of being fixedly supported by a bolt or the like. In addition, the side opposite to the support piece side at the lower end portion of the seated sensor bracket 22 is a hypotenuse that gradually narrows the seated sensor bracket 22 toward the lower side.

  The presence sensor 23 provided at the lower end portion of the presence sensor bracket 22 extending downward from the base plate 18 in this way is against the welding bolt 102 in a state of standing on the inspection target surface 104 of the workpiece 101. The presence or absence of the welding bolt 102 is detected at the upper position. As the presence sensor 23 capable of detecting the presence or absence of the welding bolt 102, for example, a photoelectric sensor can be used. When a photoelectric sensor is used as the seating sensor 23, the light emitted from the light projecting portion of the photoelectric sensor is reflected by the upper end surface of the welding bolt 102 and returned by the light receiving portion to detect the presence or absence of the welding bolt 102. Or the presence or absence of deviation from a predetermined position can be detected from the amount of reflected light. In addition, as long as the presence sensor 23 has a function of detecting the presence or absence of the welding bolt 102 and the positional deviation, a sensor other than the photoelectric sensor can be appropriately selected and used.

  A pressing tip detection sensor 25 is provided in front of a substantially central portion in the left-right direction of the main body portion of the base plate 18 via a pressing tip detection sensor bracket 24. The pressing tip detection sensor bracket 24 is a substantially rectangular plate-like member, and is provided in a state where the rear side is fixed to the lower surface side of the base plate 18 and protrudes forward from the base plate 18. The pressing tip detection sensor bracket 24 has a rectangular plate shape in which two corners of the tip portion on the protruding side thereof are chamfered, and the upper surface of the rear portion is in contact with the lower surface of the base plate 18 with the surface direction being the vertical direction. The base plate 18 is fixed.

  Thus, the pressing tip detection sensor 25 is provided on the protruding portion of the pressing tip detection sensor bracket 24 protruding forward from the base plate 18. The pressing tip detection sensor 25 is supported by the pressing tip detection sensor bracket 24 so that the detection direction is vertically downward. The pressing tip detection sensor 25 has a rod-like or cylindrical outer shape as a whole, and most of the pressing tip detection sensor 25 is erected on the upper surface of the pressing tip detection sensor bracket 24 and a detection unit (detection) on the lower surface side of the pressing tip detection sensor bracket 24. Surface).

  Specifically, at a substantially central portion of the front edge portion on the C chamfering side of the pressing tip detection sensor bracket 24, a window (not shown) through which the detection surface of the pressing tip detection sensor 25 can be visually recognized is penetrated. A nut 58 is welded to the upper surface of the bracket 24 in a state of being formed and communicating with the window. The pressing tip detection sensor 25 is fixedly supported to the pressing tip detection sensor bracket 24 by screwing the pressing tip detection sensor 25 to the nut 58 by a screw portion (not shown) formed at the tip of the pressing tip detection sensor 25. Is done. By configuring in this way, the position of the pressing tip 40, which will be described later, in the left-right direction is indirectly detected by the pressing tip detection sensor 25 detecting the pressing joint 37 that is connected to the pressing tip 40 and moves integrally with the pressing tip 40. Can be confirmed.

  As the pressing tip detection sensor 25, for example, a photoelectric sensor can be used. When a photoelectric sensor is used as the pressing tip detection sensor 25, the light emitted from the light projecting portion of the photoelectric sensor is reflected by the detection surface 48 of the detecting portion 47 of the press joint 37 described later and is detected by the light receiving portion. Thus, the position of the pressing tip 40 can be detected. Further, as long as it has a function of detecting the position of the pressing tip 40, a sensor other than the photoelectric sensor can be appropriately selected and used as the pressing tip detection sensor 25.

  A pressure switch 26 is provided on the upper surface of the base plate 18. The pressure switch 26 has a rectangular block-shaped housing, and includes a display unit 27 and a plurality of switches 28 for setting and confirming pressure. The display unit 27 and the plurality of switches 28 are disposed on one surface of the casing of the pressure switch 26. The pressure switch 26 is disposed on the surface of the base plate 18 where the display unit 27 and the like are disposed. Provided to be on the front side. The pressure switch 26 is fixedly supported on the upper surface of the base plate 18 by an L-shaped bracket 29 on the side opposite to the side where the display unit 27 and the like are disposed, that is, on the rear side. The pressure switch 26 controls the pressure of a cylinder mechanism 33 of the urging mechanism 16 described later, and enables the welding bolt 102 to be pressed with a predetermined pressure set by the switch 28. In the present embodiment, the two pressure switches 26 are provided between the pair of support plates 20 and 20 in the left-right direction, and the left and right of the central portion where the seat sensor bracket 22 and the pressing tip detection sensor bracket 24 of the base plate 18 are provided. It is arranged on both sides.

  As described above, the main body portion 15 of the weld bolt inspection unit 2 is configured, but the shape, structure, and the like of each portion are not limited to the present embodiment, and various types are possible within the scope of the gist of the present invention. Deformation / change is possible.

  Next, the urging mechanism 16 of the welding bolt inspection unit 2 will be described. As shown in FIGS. 3, 4, and 5, the urging mechanism portion 16 is disposed between the left and right support plates 20, 20 that are suspended from the main body portion 15, and the right and left of the main body portion of the base plate 18. A pair of urging mechanisms 32 configured to be bilaterally symmetric about a substantially central position in the direction are provided. Each urging mechanism 32 is provided in a state of being supported by a support plate 20 located on the opposite side of the opposing urging mechanism 32 side. In the following description, with respect to the biasing mechanism 32, the opposing biasing mechanism 32 side (the central portion side in the left-right direction of the base plate 18) is referred to as “inside”, and the opposite side (the support plate 20 side receiving the support). ) Is “outside”.

  The urging mechanism 32 mainly includes a pressing portion 36 that presses the welding bolt 102, a cylinder mechanism 33 that moves the pressing portion 36 back and forth along a predetermined direction, two shafts 34 and 34, and a bearing portion 35. Has been. The urging mechanism 32 presses the welding bolt 102 from the side by the reciprocating operation of the cylinder mechanism 33.

  As for the specific structure of each part, the cylinder mechanism 33 includes a cylinder tube 41 (outer cylinder) and a piston rod 39 provided in a state of being inserted into the cylinder tube 41. The cylinder mechanism 33 is an air cylinder provided with an air supply port 42 and an exhaust port 43 on the peripheral surface of the cylinder tube 41, and is configured as a double-action single rod cylinder. In the present embodiment, the air supply port 42 and the exhaust port 43 are both provided on the front side of the cylinder tube 41, the air supply port 42 is provided on the outside, and the exhaust port 43 is provided on the inside. The cylinder mechanism 33 performs air supply / exhaust control on the supply / exhaust ports 42 and 43, so that the piston rod 39 protrudes and retracts from the cylinder tube 41 and expands and contracts substantially in the left-right direction. By supplying air to the air supply port 42, the amount of protrusion of the piston rod 39 from the cylinder tube 41 increases, and the cylinder mechanism 33 extends. On the other hand, when the cylinder mechanism 33 is shortened by reducing the protruding amount of the piston rod 39 from the cylinder tube 41, air is supplied to the exhaust port 43.

  The cylinder mechanism 33 is provided in a state of being supported by the support plate 20 with the side where the piston rod 39 protrudes and retracts from the cylinder tube 41 being the inside. Therefore, for example, the left cylinder mechanism 33 is provided in a state in which the left side surface of the cylinder tube 41 is brought into contact with the lower portion of the inner wall surface (right side) of the left support plate 20 and is fixed by a bolt or the like (not shown). It is done.

  The two shafts 34, 34 are arranged in parallel to each other at a predetermined interval in the front-rear direction with the left-right direction as the extending direction (axial direction) above the cylinder mechanism 33. The shaft 34 is supported by the support plate 20 so as to be movable in a direction parallel to the axial direction (stretching direction) of the cylinder mechanism 33 as the cylinder mechanism 33 expands and contracts. The shaft 34 penetrates through the support plate 20 so that the outer end protrudes from the outside of the support plate 20, and the inner end is positioned inside the position of the inner end of the cylinder tube 41 of the cylinder mechanism 33. Is arranged. The support plate 20 has shaft holes 44 for passing through the two shafts 34 at two locations.

  The bearing portion 35 functions as a bearing portion of the shaft 34 that penetrates the shaft 34 together with the support plate 20 and moves in the left-right direction as described above. The bearing portion 35 is, for example, a bearing (not shown) such as a “slide bearing” or a “rolling bearing” that can slide in the axial direction while the outer peripheral edge of the shaft 34 abuts on the inside. The bearing portion 35 is placed and fixed on the outer side of the upper surface of the cylinder tube 41 of the cylinder mechanism 33, and on the two shaft holes 44 formed in the support plate 20 and the bearing portion 35 on the upper portion of the inner wall surface of the support plate 20. A state in which the outer surface of the bearing portion 35 is brought into contact with the inner surface of the support plate 20 and is fixed to the support plate 20 with bolts or the like (not shown) in a state where the two formed shaft insertion holes 45 are in communication. Provided. Thus, the shaft 34 is inserted into the shaft insertion hole 45 of the bearing portion 35 and the shaft hole 44 of the support plate 20.

  The pressing portion 36 includes a pressing joint 37 and a pressing tip 40. The pressing joint 37 is a substantially columnar member extending in the vertical direction, and is disposed inside the cylinder mechanism 33. On the upper part of the pressure joint 37, the tip end side of the piston rod 39 of the cylinder mechanism 33 and the inner end of the shaft 34 are fixed. Here, the piston rod 39 and the shaft 34 are fastened and fixed to the outer surface of the pressure joint 37 by bolts or the like, for example, by forming a female screw portion at an end portion fixed to the pressure joint 37 side. As described above, the piston rod 39 of the cylinder mechanism 33 and the two shafts 34 and 34 are connected to each other via the pressure joint 37. A pressing tip 40 is provided at the lower end of the pressing joint 37.

  Further, as described above, the pressure joint 37 has a joint portion 46 as a substantially prismatic portion that is a portion to which the piston rod 39 and the shaft 34 are fixed and extends in the longitudinal direction. The detection part 47 of the substantially prismatic shape which protrudes toward the front from the upper end part of this. The pressing joint 37 is formed in a substantially L shape as a whole in a side view (viewed in the axial direction of the shaft 34) by the joint portion 46 and the detection portion 47. The detection unit 47 protrudes forward in the left-right direction at a position slightly offset inward from the position where the joint unit 46 extends downward. Further, a convex portion protruding upward at a substantially right angle is formed at the front end portion of the detection portion 47, and the upper surface of the convex portion is used as the detection surface 48. That is, the detection unit 47 has a substantially L shape in a side view by a portion projecting forward from the joint portion 46 and a convex portion projecting upward from the distal end portion of the projecting portion, and the distal end of the convex portion. The surface (upper end surface) is the detection surface 48.

  The pressing tip 40 is provided so as to protrude inward from the pressing joint 37, and the protruding tip surface is a pressing surface 49 that presses and contacts the welding bolt 102. The pressing tip 40 has a tapered shape so that the dimension in the vertical direction gradually decreases from the outer side (the joint portion 46 side) to the inner side (the pressing surface 49 side) in the lower portion of the inner side surface of the joint portion 46. It is provided as a block-shaped part. Specifically, the pressing tip 40 has a rectangular shape in which the pressing surface 49 has a longitudinal direction in the front-rear direction, and the vertical dimension is symmetrical in the vertical direction from the contact surface side with the joint portion 46 toward the pressing surface 49. It is formed to be smaller. That is, when the pressing surface 49 is the tip, the tip end is substantially sharp in the horizontal direction from the outside to the inside.

  As described above, the welding bolt inspection unit 2 of the present embodiment moves the pressing portion 36 connected to the tip of the piston rod 39 so as to freely advance and retract in the left-right direction by the advance / retreat operation of the piston rod 39 of the cylinder mechanism 33. Yes, the welding bolt 102 is pressed from the side by the pressing tip 40 disposed at the tip of the pressing joint 37. In addition, two shafts 34, 34 that slide parallel to the axial direction of the cylinder mechanism 33 are connected to the pressure joint 37, and a bearing portion that supports the shafts 34, 34 is provided on the outer side of the upper surface of the cylinder mechanism 33. 35 is disposed and plays a role of relaxing the bending moment of the pressure joint 37 together with the shaft 34.

  With the above-described configuration, the piston rod 39, the pressing joint 37, the pressing tip 40, and the two shafts 34 and 34 are integrally moved in the left-right direction by the forward / backward movement of the piston rod 39 of the cylinder mechanism 33. To do. Accordingly, the pressing joint 37 can move to the left and right as the piston rod 39 of the cylinder mechanism 33 extends and contracts. Then, the pressing tip 40 and the detecting portion 47 that are configured integrally with the pressing joint 37 also move simultaneously. The movement of the pressing tip 40 enables pressing on the welding bolt 102, and the movement of the detecting portion 47 is performed by pressing. When the pressing surface 49 of the tip 40 moves beyond the position of the predetermined welding bolt 102 (when the welding bolt 102 is removed), it can be detected.

  In the pressing joint 37, the detection portion 47 is configured to be offset inward with respect to the joint portion 46 by detecting the detection surface 48 of the detection portion 47 with the pressing tip detection sensor 25, that is, the tip of the pressing tip 40. This is because the position of the surface (pressing surface 49) in the horizontal direction (left-right direction) is indirectly detected by detecting the detection surface 48. In the present embodiment, the pressing tip 40 and the detection portion 47 are a portion provided integrally with the joint portion 46, that is, a portion having a constant relative positional relationship. Move as a unit.

  Therefore, by detecting the position of the detection surface 48 provided in the detection unit 47 in the left-right direction by the pressing tip detection sensor 25, the position of the pressing tip 40 in the left-right direction is derived from the position of the detection surface 48. The pressing portion 36 of the present embodiment is configured such that the position of the inner wall surface of the detection portion 47 that is the position of the inner end of the detection surface 48 is the position of the pressing surface 49 of the pressing tip 40 as it is in the left-right direction. . Therefore, the inner wall surface of the detection unit 47 is positioned on the same plane along the vertical direction as the tip surface (pressing surface 49) of the pressing tip 40 positioned below the detection unit 47.

  As described above, the welding bolt inspection unit 2 of the present embodiment relates to the position of the pressing surface 49 of the pressing tip 40 that is a portion in contact with the welding bolt 102 in the left-right direction, and determines the position of the pressing surface 49 by the pressing tip detection sensor 25. Instead of directly detecting, the detection tip 48 positioned above the pressing surface 49 and in front of the base plate 18 and extending from the joint portion 46 so as to form a surface at the same position as the pressing surface 49 is pressed. A configuration to be detected by the detection sensor 25 is employed.

  Further, the position of the pressing surface 49 of the pressing tip 40 in the left-right direction is set to a position where the welding bolt 102 is completely removed by the pressing tip 40 when the piston rod 39 protrudes from the cylinder tube 41 to the maximum extent. Has been. The state where the welding bolt 102 is completely removed is detected by the pressing tip detection sensor 25. The offset amount in the left-right direction between the detection portion 47 and the joint portion 46 is defined in accordance with the position of the pressing surface 49 interlocking with the operation of the cylinder mechanism 33.

  If configured as described above, as shown in FIG. 7A, the pressed tip detection sensor 25 does not detect the detection surface 48 when the welding bolt 102 is not completely detached from the workpiece 101. In this state, however, the presence sensor 23 located immediately above the welding bolt 102 does not detect the welding bolt 102, so that a problem that the welding bolt 102 does not exist at a predetermined position can be detected.

  Furthermore, even in the case shown in FIG. 7A, the light receiving sensitivity by the pressing tip detection sensor 25 is adjusted to detect this even if the welding bolt 102 is not completely detached. Can do.

  Further, as shown in FIG. 7B, the offset amount between the detection part 47 and the joint part 46 is formed such that the position of the inner wall surface of the detection part 47 is inside the pressing surface 49 of the pressing tip 40. Then, even if the piston rod 39 does not protrude to the maximum extent, it can be detected that the pressing tip 40 has moved past a predetermined position of the welding bolt 102. As a result, it is possible to detect the welding bolt 102 that is not completely detached from the workpiece 101, and the seat sensor 23 positioned immediately above the welding bolt 102 does not detect the welding bolt 102. Trouble can be detected in duplicate.

  Furthermore, by configuring the detection unit 47 and the joint part 46 as separate members, the offset amount between the detection part 47 and the joint part 46 can be adjusted. Specifically, as shown in FIG. 8, in a welding bolt inspection unit 2 ′ as a modification, the detection unit 47 and the joint unit 46 are configured as separate members. A long hole 52 whose longitudinal direction is the left-right direction is formed in a fixing portion of the detecting portion 47 with respect to the joint portion 46, and the detecting portion 47 is fastened and fixed to the joint portion 46 by a bolt 53 passing through the long hole 52. . With such a configuration, the offset amount between the detection unit 47 and the joint unit 46 can be adjusted. If comprised in this way, while being able to adjust freely the detection of the state which the welding volt | bolt 102 completely removed as mentioned above, or the state which is not completely removed, it is possible to adjust freely between the press front-end | tip detection sensor 25 and a detection surface. Subtle position adjustment can be easily performed.

  In the weld bolt inspection unit 2 according to the present embodiment, the pair of urging mechanisms 32 are symmetrically configured about the substantially central position in the left-right direction of the main body portion of the base plate 18. Therefore, the welding bolt inspection unit 2 includes the cylinder mechanism 33 and the pressing portion 36 as a pair of symmetrical structures so as to face each other in the axial direction of the cylinder mechanism 33 via the seat sensor 23. With such a configuration, the same pressing tip detection sensor 25 is configured to be commonly used in relation to the detection unit 47 of each urging mechanism 32.

  On the other hand, for example, if the pressing tip detection sensor 25 is provided separately for each of the urging mechanisms 32, 32, the pressing tip detection sensor 25 is not offset with respect to the joint portion 46 of the detection unit 47. Regardless of the state of the welding bolt 102, it is possible to cope with detection of an arbitrary position of the pressing tip 40 to be detected by making it movable.

  According to the weld bolt inspection unit 2 and the weld bolt inspection apparatus 1 according to the present embodiment as described above, a weld inspection for the weld bolt 102 can be performed with high accuracy, and a normal inspection system is always maintained. be able to. Specifically, the presence / absence, displacement, and welding strength of the welding bolt 102 can be reliably inspected with a single inspection for each welding bolt 102, thereby shortening the inspection time and improving the inspection accuracy. Can be planned.

  Moreover, since the welding bolt inspection unit 2 according to the present embodiment detects the displacement of the welding bolt 102 by the detection by the presence sensor 23 and the pressing inspection by the pressing portion 36, the position of the welding bolt 102 is shifted. The position shift of the welding bolt 102 can be accurately detected without overlooking the above.

  The welding bolt inspection unit 2 according to the present embodiment is attached to the robot 3 and moved three-dimensionally by the operation of the robot 3 to inspect each welding bolt 102. For this reason, for example, compared to a configuration in which an inspection mechanism having a cylinder mechanism or the like is provided for each of the plurality of welding bolts 102, it is possible to flexibly cope with a plurality of types of workpieces having different arrangement positions of the welding bolts 102. Sex is obtained.

  Further, by moving the welding bolt inspection unit 2 by the operation of the robot 3 with respect to the plurality of welding bolts 102 formed on the workpiece 101, all the welding bolts 102 can be inspected by one welding bolt inspection apparatus 1. Therefore, the configuration of the apparatus can be simplified, and maintenance of the apparatus can be easily performed.

  In the weld bolt inspection unit 2 of the present embodiment, the pressing portion 36 has a pressing tip 40 disposed at a position shifted in the radial direction of the cylinder mechanism 33 with respect to the axial position of the cylinder mechanism 33. In the present embodiment, in the weld bolt inspection unit 2, the joint portion 46 of the pressure joint 37 is disposed so as to protrude below the lower end position of the cylinder mechanism 33 (specifically, the lower end position of the cylinder tube 41). Yes. Accordingly, the pressing tip 40 is disposed at a distance in the radial direction of the cylinder mechanism 33 with respect to the axial direction of the cylinder mechanism 33 so as to be positioned at a portion protruding downward from the lower end position of the cylinder mechanism 33. Yes.

  Specifically, the joint portion 46 of the pressure joint 37 is provided below the cylinder mechanism 33 and at the tip of the seated sensor bracket 22 extending downward from the center portion of the base plate 18, and the welding bolt 102. Is extended to a position below the position of the seated sensor 23 that detects from above, and a pressing tip 40 is disposed at the tip. Thereby, the cylinder mechanism 33 itself does not interfere with the welding bolt 102.

  Further, it is possible to detect the welding strength and the like of the welding bolt 102 by pressing the welding bolt 102 with the pressing tip 40 while detecting the presence or absence of the welding bolt 102 by the presence sensor 23. That is, the welding bolt inspection unit 2 according to this embodiment welds the welding bolt 102 with the pressing tip 40 in a state where the presence sensor 23 can detect the presence or absence of the welding bolt 102 with respect to the welding bolt 102. The welding strength of the welding bolt 102 is inspected by pressing from the radial direction of the bolt 102.

  Further, even in a situation where a plurality of welding bolts 102 are densely packed as shown in FIG. 9, it is possible to inspect the welding bolts 102 to be inspected without interfering with other welding bolts 102. For example, if a pressing tip 40 that is a pressing portion against the welding bolt 102 is provided on an extension of the piston rod 39 that is a movable portion of the cylinder mechanism 33, the pressing tip 40 is in a state of standing on the inspection target surface 104 of the workpiece 101. If the welding bolt 102 is to be pressed from the side by the pressing tip 40, the cylinder mechanism 33 needs to be positioned at substantially the same height as the welding bolt 102 with respect to the inspection target surface 104. In such a case, as shown in FIG. 9, in a situation where a plurality of welding bolts 102 are densely packed, the cylinder mechanism 33 interferes with the welding bolts 102 other than the object to be pressed.

  Therefore, like the welding bolt inspection unit 2 according to the present embodiment, the pressing tip 40 that is moved by the operation of the cylinder mechanism 33 is moved from the position of the piston rod 39 of the cylinder mechanism 33 to the outside in the radial direction of the cylinder mechanism 33 (this embodiment). It is provided at the tip of the pressure joint 37 extended downward (in the form), and the movement position of the pressure tip 40 is shifted from the position of the piston rod 39, so that the interference with the welding bolt 102 of the cylinder mechanism 33 as described above is caused. It is possible to press the welding bolt 102 without causing it.

  Moreover, since the welding bolt inspection unit 2 of this embodiment is provided with the urging mechanism 32 on the left and right sides, the time difference can be obtained without moving the position of the welding bolt inspection unit 2 with respect to one welding bolt 102. Since the opposite pressing force can be applied, the processing time can be minimized and the inspection accuracy can be improved.

  Furthermore, it is possible to inspect a single welding bolt 102 from a plurality of directions simply by rotating the hand portion 11 of the robot 3.

  In addition, as shown in FIG. 1, the welding bolt inspection apparatus 1 according to the present embodiment includes a pseudo inspection unit 5 for periodically confirming whether each mechanism of the welding bolt inspection unit 2 operates normally. I have. In the pseudo-inspection unit 5, a pseudo-bolt 55 having substantially the same shape as the welding bolt 102 that is an object to be inspected is fixed on a rectangular block 54 formed of a heavy object such as metal fixed to the floor. .

  With respect to the pseudo bolt 55, the hand portion 11 of the robot 3 is moved, and the welding bolt inspection unit 2 is positioned in a manner of inspecting the welding bolt 102. In this state, it can be confirmed that the seat sensor 23 detects the pseudo bolt 55, and further, even if the pressing tip 40 presses the pseudo bolt 55, the pressing tip detection sensor 25 does not detect the pressing tip 40. That is, if the presence sensor 23 does not detect the pseudo bolt 55, the presence sensor 23 has failed, or the positioning deviation by the robot 3 has occurred. When the pressing tip 40 is detected, it is possible to confirm whether or not the shape of the pressing tip 40 is deformed, a state in which the pressing tip 40 is dropped from the joint portion 46, or the like.

  In addition, a load cell (not shown) is connected to the pseudo bolt 55 as means for confirming whether or not the pressing force applied to the pseudo bolt 55 from the pressing tip 40 by the cylinder mechanism 33 can output a predetermined pressure. You can also. Thus, along with the above confirmation, it can be confirmed whether or not the intended normal pressure is applied to the pseudo bolt 55 (weld bolt 102) via the pressing tip 40.

  Thus, by configuring the pseudo-inspection unit 5, even if the air pressure supplied to the cylinder mechanism 33 is normal, air leaks due to damage inside the cylinder mechanism 33 and the piston rod 39 are caught. In addition, by checking the pressing force output from the pressing tip 40, the inspection accuracy can be maintained at a certain level.

  Further, if the pseudo inspection using the pseudo inspection unit 5 is performed every time before the inspection of one workpiece 101 is started, the welding bolt 102 which is originally incompatible with the inspection due to the defect on the side of the welding bolt inspection apparatus 1 is provided. It is possible to prevent the held workpiece 101 from being dispensed to the next process. Therefore, a highly reliable product can be shipped reliably.

  Next, the use procedure of the welding bolt inspection apparatus 1 according to the present embodiment will be described with reference to FIG.

  First, as shown in FIG. 10, the type of workpiece 101 to be inspected is determined (step S1). Thereby, based on the kind data recorded in advance, the position data of the welding bolt 102 corresponding to the kind of workpiece 101 to be inspected by the welding bolt inspection apparatus 1 is transferred to the welding bolt inspection apparatus 1.

  Next, the welding bolt inspection apparatus 1 moves to a preset origin position (step S2). As the origin position, a position that does not interfere with other transfer robots (not shown) or the like is arbitrarily set.

  Next, the transfer robot grips the workpiece 101 of the target product type and places it on the inspection table 4 (step S3).

  Whether or not the workpiece 101 is normally set on the inspection table 4 is confirmed by a plurality of workpiece detection sensors of the inspection table 4 (step S4).

  If the detection of the workpiece 101 is not recognized after a predetermined time has elapsed, all the operations are stopped and an error is left (step S5).

  When the workpiece 101 is normally set on the inspection table 4, the arms of the welding bolt inspection device 1 are moved, and the pseudo bolt 55 formed in the pseudo inspection portion 5 by the welding bolt inspection unit 2. A pseudo test is performed (step S6).

  In the pseudo test, when the seat sensor 23 does not detect the pseudo bolt 55, or when the press tip 40 is detected by the press tip sensor 25 in the press test, or the load cell connected to the pseudo bolt 55 is within a predetermined pressure range. If not, all operations are stopped and an error is notified (steps S7 and S8).

  In the pseudo inspection, when the above-described defect is not detected, the welding bolt inspection unit 2 moves above the initially planned welding bolt 102 formed on the workpiece 101 (steps S7 and S9).

  When the presence sensor 23 does not detect the welding bolt 102 due to the presence or absence of the welding bolt 102 or the inclination, all the operations are stopped and an error is notified (steps S10 and S11).

  When the presence sensor 23 detects the welding bolt 102, a press inspection by the welding bolt inspection unit 2 is performed (steps S10 and S12).

  When the pressing tip detection sensor 25 detects the pressing tip 40 by the pressing test, all operations are stopped and an error is notified (steps S13 and S14).

  When the pressing tip 40 is not detected by the pressing tip 40 by the pressing test (step S13), the presence sensor 23 detects the welding bolt 102 (step S15). If the welding inspection causes the welding bolt 102 to be inclined and the welding bolt 102 is not detected, all operations are stopped and an error is notified (steps S15 and S16).

  Next, when there is another welding bolt 102 to be inspected on the same workpiece 101 (step S17), the process returns to step S9 and the above-described processing is repeated until step S17.

  When the inspection of all the welding bolts 102 on the workpiece 101 is completed (step S17), it is confirmed whether there is another workpiece 101 to be inspected next (step S18).

  In this case, if there is no change of the workpiece 101 type (step S20), the process returns to step S2 and the above-described processing is repeated until step S18.

  When there is a change in the workpiece 101 type (step S20), the process returns to step S1 and the above-described processing is repeated until step S18.

  If there is no workpiece 101 to be inspected next (step S18), the welding bolt inspection apparatus 1 is moved to the origin position (step S19), and all the processes are completed.

  As described above, the usage procedure of the welding bolt inspection apparatus 1 according to the present embodiment is an example of a usage procedure for making the structure of each component such as the welding bolt inspection unit 2 easier to understand. Yes, the present invention is not limited to this use procedure.

  The weld bolt inspection unit 2 according to this embodiment includes two urging mechanisms 32. However, as long as at least one urging mechanism 32 is provided, it is within the scope of the present invention.

  The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the specific embodiments, and various modifications and changes can be made within the scope of the gist of the present invention described in the claims. It can be changed.

DESCRIPTION OF SYMBOLS 1 Welding bolt test | inspection apparatus 2 Welding bolt test | inspection unit 3 Robot 4 Test stand 5 Pseudo test | inspection part 11 Hand part 23 Seated sensor 25 Pressing tip detection sensor 33 Cylinder mechanism 36 Pressing part 40 Pressing tip 101 Work 102 Welding bolt 102A Stud bolt 102B Weld bolt

Claims (5)

A welding bolt inspection unit that automatically and sequentially inspects the presence and absence of a plurality of welding bolts attached to the arm tip of the robot and welded to a predetermined part of the workpiece, and the welding strength;
A presence sensor capable of detecting the presence or absence of the welding bolt;
A pressing portion for pressing the welding bolt;
A cylinder mechanism for moving the pressing portion forward and backward,
The pressing portion has a pressing tip disposed at a position shifted in the radial direction of the cylinder mechanism with respect to the axial position of the cylinder mechanism,
A welding bolt inspection unit that inspects the welding strength by pressing the welding bolt from a radial direction of the welding bolt by the pressing tip.   The welding bolt inspection unit according to claim 1, further comprising a pressing tip detection sensor capable of detecting the position of the pressing tip at a position moved beyond the position of the welding bolt.   The said cylinder mechanism and the said press part are provided as a pair of symmetrical structure so that it may mutually oppose in the axial direction of the said cylinder mechanism via the said presence sensor, The Claim 1 or Claim 2 characterized by the above-mentioned. Weld bolt inspection unit. A welding bolt inspection apparatus comprising the welding bolt inspection unit according to any one of claims 1 to 3,
A robot that is connected to the welding bolt inspection unit and is movable;
An inspection table on which the workpiece can be placed;
The welding bolt inspection unit is moved by the robot, and the presence / absence and welding strength of a plurality of welding bolts welded to a predetermined portion of the workpiece placed on the inspection table are sequentially and automatically inspected. Welding bolt inspection device.   The welding bolt inspection apparatus according to claim 4, further comprising a pseudo inspection unit for confirming the operation of the welding bolt inspection unit in a pseudo manner.

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