JP6450275B2 - Screw hole inspection device and screw hole inspection method - Google Patents

Description

  The present invention relates to a screw hole inspection device and a screw hole inspection method.

  There is a screw hole inspection device for inspecting a screw hole of a workpiece subjected to screw machining. There exists a thing disclosed by patent document 1, for example in a screw hole test | inspection apparatus. In Patent Document 1, a screw gauge is attached to a robot adapter, and the screw hole of the screw gauge is inspected by screwing the screw portion of the screw gauge into the screw hole of the workpiece by rotating the adapter.

Japanese Patent No. 5447474

  By the way, in a chain block or the like for lifting a load, a multi-threaded screw is formed on a component called a female screw. This multi-threaded screw is formed by pressing a work tap that will later become a female screw while rotating a dedicated tap attached to a drilling machine or the like.

  In such a multi-thread screw, the lead becomes larger than a normal thread (single thread), and it is necessary to form a screw groove corresponding to the number of threads with a dedicated tap. Therefore, the length of the dedicated tap becomes longer depending on the lead and the number of strips. In addition, the dedicated tap for multi-thread screws has a large lead, so the amount of cutting per unit length is also large, so the load at the time of thread cutting is large compared to the tap for single thread screws, and the tool Life is shortened. Therefore, in order to maintain the accuracy of the multi-thread screw, it is necessary to inspect the screw hole of the workpiece using an inspection jig. Moreover, it is necessary to manage the lifetime of the exclusive tap for multi-threaded screws based on the inspection.

  However, although the configuration disclosed in Patent Document 1 discloses the inspection of the screw hole related to the single thread, the inspection method is not disclosed for the screw hole of the multi-thread screw having a large lead. In particular, in multi-threaded screws, the lead is larger than in single-threaded screws. Therefore, in multi-threaded screws, there is some processing failure in inspections in which the inspection jig is always forcedly rotated by a motor or the like. However, it may pass the inspection.

  The present invention has been made based on the above circumstances, and an object thereof is to provide a screw hole inspection device and a screw hole inspection method capable of inspecting a processing defect well for screw holes of a multi-thread screw of a workpiece. To do.

  In order to solve the above problems, according to a first aspect of the present invention, there is provided a screw hole inspection device for inspecting screw holes of a multi-thread screw formed in a work, wherein the work is placed, A mounting portion having an insertion portion that communicates with the screw hole, an inspection jig having a multi-threaded screw portion that is screwed into the screw hole of the workpiece through the insertion portion, and the inspection jig are placed By moving the jig mounting base and the multiple threads of the inspection jig relative to the screw holes, the workpiece is supported by the inspection jig, and at least the weight of the workpiece is used in the support state. Based on the detection mechanism transmitted by the moving mechanism for screwing the multi-threaded screw portion into the screw hole, the detecting means for detecting whether or not the workpiece is positioned at the screwing completion position with respect to the inspection jig, and the like. To determine whether the screw hole is normal. Screw holes inspection apparatus characterized by comprising a control means for controlling the actuation of the moving mechanism is provided.

  According to another aspect of the present invention, in the above-described invention, the moving mechanism moves the jig mounting base vertically upward, and the multi-threaded screw portion is completely screwed into the screw hole in the inspection jig. When the workpiece is in contact with the workpiece, the step is positioned so that the workpiece is positioned. When the inspection tool is located at the detection position, the detection means determines whether the workpiece is located at the step. It is preferable to detect whether or not.

  Furthermore, in another aspect of the present invention, in the above-described invention, the inspection jig is attached to the jig mounting base by fitting in an uneven shape, so that the inspection jig is attached to the jig mounting base. It is preferably slidable in the rotational direction and the vertical direction, and the jig mounting base is preferably provided with a base rotating mechanism whose rotational operation is controlled by the control means.

  Further, according to another aspect of the present invention, in the above-described invention, after the contact, the operation of the moving mechanism is controlled so that the multi-threaded screw portion is brought into contact with the screw hole of the workpiece placed on the placing portion. Control the operation of the moving mechanism to raise the jig mounting base and the inspection jig, lift the work piece with the inspection jig, and when the inspection jig is located at the detection position, the work will be in the screwing completion position. It is detected whether it is positioned, and the operation of the moving mechanism is controlled so that the jig mounting base and the inspection jig are lowered, and the work is placed on the mounting portion, and further jig mounting base and inspection treatment are performed. It is preferable to remove the screw of the multi-threaded screw portion from the screw hole by lowering the tool.

  According to a second aspect of the present invention, there is provided a screw hole inspection method for inspecting a screw hole of a multi-thread screw formed in a workpiece using an inspection jig, the inspection jig being provided with the workpiece The multi-threaded screw portion to be screwed into the screw hole is moved relative to the screw hole to realize the workpiece support state by the inspection jig, and at least the workpiece's own weight is utilized in the support state. Based on a screwing step for screwing the threaded portion into the screw hole, a detection step for detecting whether or not the workpiece is positioned at a screwing completion position with respect to the inspection jig, and a detection signal transmitted from the detection step And a determination step of determining whether or not the screw hole is normal.

  According to the present invention, in the screw hole inspection device and the screw hole detection method, the screwing operation of the inspection jig to the workpiece is performed using the screwing operation to the inspection jig due to the drop of the workpiece due to its own weight (including relative fall). By monitoring the insertion state, it is possible to easily and accurately inspect the screw holes of the multi-threaded screw.

1 is a side view illustrating a schematic overall configuration of a screw hole inspection device according to an embodiment of the present invention. It is a side view which shows the structure of the test | inspection jig | tool used with the screw hole test | inspection apparatus shown in FIG. In the screw hole inspection apparatus shown in FIG. 1, it is a figure which shows a mode that an inspection jig | tool is reversely raised. In the screw hole inspection apparatus shown in FIG. 1, it is a figure which shows a mode when a multiple thread | screw part touches a screw hole. In the screw hole inspection apparatus shown in FIG. 1, it is a figure which shows a mode that a test | inspection jig | tool raises forward rotation. In the screw hole inspection apparatus shown in FIG. 1, it is a figure which shows a mode that the workpiece | work W is detected by the abnormality detection sensor in the detection position which stopped the raise of the workpiece | work. In the screw hole inspection apparatus shown in FIG. 1, it is a figure which shows the state by which the workpiece | work and the test | inspection jig were lowered | hung and the workpiece | work was mounted in the mounting plate. It is a figure which shows the operation | movement flow of this Embodiment.

  Hereinafter, a screw hole inspection device and a screw hole inspection method according to an embodiment of the present invention will be described with reference to the drawings.

<1. Overall configuration of screw hole inspection device>
FIG. 1 is a side view showing a schematic overall configuration of the screw hole inspection apparatus 10. As shown in FIG. 1, the screw hole inspection device 10 includes a table 20, a mounting plate 30, a guide mechanism 40, a plate up / down mechanism 50, a clamp mechanism 60, a work transport mechanism 70, and a work discharge mechanism 80. The main components are the abnormality detection sensor 90, the inspection jig 100, the jig mounting base 110, the base vertical mechanism 120, the base rotating mechanism 130, and the control unit 140.

  The table 20 is a metal plate-like portion, and various members are attached thereto. Further, the table 20 is provided with an insertion hole 21 for inserting an inspection jig 100 described later.

  The placement plate 30 is a member on which the workpiece W is placed, and corresponds to a placement portion. The mounting plate 30 contacts and separates from the table 20, but the contact and separation are guided by the guide mechanism 40. The mounting plate 30 is also provided with an insertion hole 31 (corresponding to the insertion part), and an inspection jig 100 described later can be inserted into the insertion hole 31. The guide mechanism 40 is a part that guides the vertical movement of the mounting plate 30. In order to perform such a guide, a guide shaft 32 is attached to the mounting plate 30, and a guide cylinder portion 22 for guiding the vertical movement of the guide shaft 32 is provided on the table 20. . The guide shaft 40 and the guide tube portion 22 constitute a guide mechanism 40.

  When the mounting plate 30 is guided to a predetermined position in the vertical direction by the guide mechanism 40, the workpiece W is moved to the upper surface of the mounting plate 30 by the work transport mechanism 70 after moving to the predetermined position above the mounting plate 30. Placed on. In order to satisfactorily place the workpiece W, a mark such as a marking (not shown) may be present on the upper surface of the placement plate 30. Further, when the mounting plate 30 is located at a predetermined position on the lower side in the vertical direction, the predetermined position on the lower side is a position for inspecting the screw hole W1 of the workpiece W.

  The plate up / down mechanism 50 is a mechanism for moving the mounting plate 30 described above up and down. In order to realize such vertical movement, a plate drive source 51 such as a motor or a cylinder is provided, and in order to transmit the drive force from the plate drive source 51, various types such as a ball screw, a gear mechanism, and a belt are provided. The drive transmission mechanism is provided.

  The clamp mechanism 60 is a mechanism for clamping the work W placed on the placement plate 30. The clamp mechanism 60 includes a pair of clamping members (not shown) for clamping the workpiece W, a clamp driving source 61 such as a motor or a cylinder, and a driving force transmission mechanism. The workpiece W can be clamped by the pair of clamping members by driving the clamp driving source 61.

  The workpiece transfer mechanism 70 is a transfer robot or the like (not shown), and includes a plurality of transfer drive sources 71, gripping arms, and the like. Then, the workpiece W is placed at a predetermined position on the upper surface of the placement plate 30 while the workpiece W is gripped by the gripping arm by the driving of the conveyance drive source 71. The workpiece transfer mechanism 70 may be a component of the screw hole inspection device 10, but may not be a component of the screw hole inspection device 10.

  The workpiece discharge mechanism 80 is a mechanism for discharging the workpiece W, which has been inspected for the screw hole W1, from the upper surface of the mounting plate 30. Such a mechanism includes a discharge drive source 81 such as a motor or a cylinder, a drive force transmission mechanism that transmits the drive force of the discharge drive source 81, and a protruding member (not shown). Examples include a protruding member capable of protruding the work W to a normal recovery position and an abnormal work W to an abnormal recovery position by driving the discharge drive source 81.

  The abnormality detection sensor 90 is a sensor for detecting whether or not there is an abnormality in the workpiece W, and corresponds to a detection unit. Specifically, when the workpiece W is screwed to a predetermined position with respect to the inspection jig 100 described later, the abnormality detection sensor 90 detects the height position of the workpiece W. In this case, when the workpiece W is not screwed to the predetermined position, the workpiece W is positioned at a position higher than the detection position of the abnormality detection sensor 90. Therefore, the workpiece W is not detected by the abnormality detection sensor 90. The screw hole is abnormal. Examples of the abnormality detection sensor 90 include a light projecting / receiving optical sensor, a transmission optical sensor, and the like. However, a contact type sensor may be used, a proximity sensor (for example, an electromagnetic induction method, a capacitance method, a method using a magnet or a reed switch, etc.) may be used, and other sensors may be used. Also good.

  Next, the inspection jig 100 will be described. The inspection jig 100 is a jig for inspecting whether there is any abnormality in the screw hole W1 of the workpiece W. FIG. 2 is a side view showing the configuration of the inspection jig 100. The inspection jig 100 includes a multi-threaded screw portion 101, a main body shaft portion 102, a stepped portion 103, a guide portion 104, and a screw chamfered portion 105.

  The multi-threaded screw portion 101 is a male thread-shaped multi-threaded screw portion that is screwed into a screw hole W1 of a multi-threaded screw formed in the workpiece W. Any number of multiple threads may be provided as long as there are two or more threads.

  The main body shaft portion 102 is a shaft-like portion that is continuous with the multi-threaded screw portion 101. In a state where the inspection jig 100 is set on the jig mounting base 110, the main body shaft portion 102 is positioned on the lower side in the vertical direction with respect to the multi-thread screw portion 101. The main body shaft portion 102 is provided with a larger diameter than the multi-threaded screw portion 101. Thus, due to the difference in diameter between the main body shaft portion 102 and the multi-threaded screw portion 101, the step portion 103 is provided at the boundary portion between them. The step portion 103 is a portion where the lower surface side of the workpiece W is received. And when the workpiece | work W contacts this level | step-difference part 103, it has been in the state which reached | attained the screwing completion position at the time of screwing the multi-threaded screw part 101 in the screw hole W1.

  Further, the main body shaft portion 102 is provided with an insertion hole 102a so as to be directed upward from the lower bottom surface thereof. The insertion hole 102a is a hole portion into which the mounting shaft 111 of the jig mounting base 110 is inserted, and the inspection jig 100 is attached to the jig mounting base 110 by such insertion. In the present embodiment, the insertion hole 102 a is provided in a round hole shape, and the inspection jig 100 is provided so as to be rotatable and removable with respect to the mounting shaft 111.

  The guide portion 104 is a portion that serves as a guide when the multi-thread screw portion 101 is screwed into the screw hole W1 of the workpiece W. In order to realize such a guide function, the guide portion 104 is provided so as to have a pointed shape toward the distal end side.

  The screw chamfered portion 105 is a portion where the upper end side of the multi-threaded screw portion 101 is chamfered. Due to the presence of the screw chamfered portion 105, the multi-threaded screw portion 101 is easily screwed into the screw hole W1 of the workpiece W. In the configuration shown in FIG. 2, a flange portion 106 is provided on the lower end side of the main body shaft portion 102 to improve stability when the inspection jig 100 is installed on the jig mounting base 110. However, a configuration in which the flange portion 106 does not exist may be employed.

  The jig mounting base 110 is a part for mounting the inspection jig 100 described above. In order to realize such mounting of the inspection jig 100, the mounting shaft 111 is provided on the jig mounting base 110 so as to protrude upward. The attachment shaft 111 is a shaft-like portion that is inserted into the insertion hole 102a, and has a diameter that the inspection jig 100 does not rattle when the attachment shaft 111 is inserted into the insertion hole 102a. .

  The pedestal vertical mechanism 120 is a mechanism for vertically moving the jig mounting base 110 described above in the vertical direction, and corresponds to a moving mechanism. In order to realize such vertical movement, a vertical drive source 121 such as a motor or a cylinder and a drive transmission mechanism selected from, for example, a gear mechanism, a belt, a pulley, and the like are provided.

  The base rotation mechanism 130 is a mechanism for horizontally rotating the jig mounting base 110 described above. In order to realize such rotation, a rotation drive source 131 such as a motor and a drive transmission mechanism selected from, for example, a gear mechanism, a belt, and a pulley are provided.

  The control unit 140 is a part that controls driving of each driving source described above, and corresponds to a control unit. The control unit 140 receives a detection signal from the abnormality detection sensor 90, and determines whether or not an abnormality has occurred in the screw hole W1 of the workpiece W based on the detection signal. When the screw hole W1 of the workpiece W is normal, the control unit 140 drives the workpiece discharge mechanism 80 to discharge the workpiece W to the normal collection position. On the contrary, when there is an abnormality in the screw hole W1 of the workpiece W, the workpiece discharge mechanism 80 is driven to discharge the workpiece W to the recovery position for abnormality.

  In addition, when using a motor in each of the drive sources 51, 61, 71, 81, 121, and 131 described above, a stepping motor capable of pulse control can be used. When using a stepping motor, high-accuracy positioning according to the number of pulses is possible.

<2. Regarding the operation flow of the screw hole inspection device 10>
Next, the operation flow of the screw hole inspection apparatus 10 will be described below. In the following description, the operation will be described according to the operation flow of FIG. 8, but a part of the operation flow will be described with reference to the operation explanatory diagrams of FIGS.

(1) First Step: Advance Preparation First, in order to inspect the screw hole W1 of the workpiece W using the inspection jig 100, the inspection jig 100 is set on the jig mounting base 110 (S1). At this time, the insertion hole 102a is inserted into the mounting shaft 111.

(2) 2nd process: Conveyance of workpiece | work W Then, the control part 140 operates the workpiece conveyance mechanism 70, and mounts the workpiece | work W in which the process of the screw hole W1 was completed on the mounting plate 30 (S2). ). Immediately before the placement, the control unit 140 operates the plate up-and-down mechanism 50 to position the placement plate 30 on the upper side, and the work plate W is placed on the placement plate 30 with the placement plate 30 located on the upper side. 30. At this time, it is preferable that the center of the insertion hole 31 and the center of the screw hole W1 are disposed substantially on the same axis. After such placement, the control unit 140 operates the plate lifting mechanism 50 to place the placement plate 30 on the lower side.

  When the work W is placed on the placement plate 30 and the work W is a lightweight work having a small weight, the clamp drive source 61 of the clamp mechanism 60 is operated to hold the work W by the holding member. Let Thereby, it is possible to realize a state in which the workpiece W is not displaced at the moment when the multi-threaded screw portion 101 is screwed into the screw hole W1. On the other hand, when the workpiece W is a heavy workpiece, since the workpiece W is not easily displaced even if the workpiece W is not clamped by the clamping member, the clamp drive source 61 of the clamp mechanism 60 is not operated. .

(3) Third step: Reverse rotation rise of inspection jig 100 Next, the control unit 140 operates the jig mounting base 110 to raise the inspection jig 100. At this time, the multi-threaded screw portion 101 is screwed. The inspection jig 100 is raised while rotating in a direction opposite to the direction screwed into the hole W1 (S3). This is shown in FIG. That is, the control unit 140 operates the vertical drive source 121 of the base vertical mechanism 120 to raise the jig mounting base 110. At the same time, the control unit 140 operates the rotation drive source 131 of the base rotation mechanism 130 to rotate the jig mounting base 110 in a direction opposite to the direction in which the multi-thread screw part 101 is screwed into the screw hole W1. . In the following description, the rotation of the inspection jig 100 in the direction in which the multi-threaded screw portion 101 is screwed into the screw hole W1 is assumed to be normal rotation, and the multi-threaded screw portion 101 is twisted into the screw hole W1 opposite thereto. Rotation of the inspection jig 100 in the direction opposite to the direction in which it is inserted is defined as reverse rotation.

(4) Fourth Step: Stopping Lifting of Inspection Jig 100 When the inspection jig 100 is raised as described above, the guide portion 104 side of the inspection jig 100 slightly touches the screw hole W1. The work W is raised and the work W is slightly lifted. FIG. 4 shows a state when the multi-threaded screw portion 101 touches the screw hole W1. In this state, the control unit 140 stops the vertical drive source 121 of the pedestal vertical mechanism 120 (S4). At this time, the rotation drive source 131 of the base rotation mechanism 130 is also stopped.

(5) Fifth Step: Forward Rise of Inspection Jig 100 Next, the control unit 140 operates the rotational drive source 131 of the base rotation mechanism 130 to cause the jig mounting base 110 to rotate forward. Along with this normal rotation, the control unit 140 operates the vertical drive source 121 of the base vertical mechanism 120 to raise the jig mounting base 110 (S5). FIG. 5 shows a state in which the inspection jig 100 is rotated forward. Then, the multi-threaded screw portion 101 is screwed into the screw hole W1. At this time, since the multi-threaded screw portion 101 is provided with the screw chamfered portion 105 (see FIG. 2), the multi-threaded screw portion 101 is easily engaged with the screw hole W1.

  Here, the relationship between the ascending speed of the jig mounting base 110, the number of rotations, and the leads of the screw hole W1 and the multi-threaded screw portion 101 is as follows. That is, V = R × L, where V is the ascending speed, R is the rotational speed, and L is the lead distance. However, the insertion hole 102a and the attachment shaft 111 are not fixed and can be displaced. Therefore, when the multi-threaded screw portion 101 is screwed into the screw hole W1, the lower bottom portion of the main body shaft portion 102 may be in contact with the mounting plate 30, but may be separated without contacting.

  When the workpiece W is a lightweight workpiece, the workpiece W is clamped by the clamping member of the clamp mechanism 60 until the multi-threaded screw portion 101 is slightly screwed into the screw hole W1. However, when the multi-threaded screw portion 101 is slightly screwed into the screw hole W1, the clamping of the workpiece W by the clamping member is released. For this reason, the multi-threaded screw portion 101 is not forcedly screwed into the screw hole W1, but is screwed into the screw hole W1 with a relatively weak screwing force such as the weight of the workpiece W and the inertia of rotation. It becomes.

(6) Raising and stopping of workpiece W When the workpiece W is raised to a predetermined detection position, the control unit 140 stops the operation of the vertical drive source 121, thereby stopping the raising of the workpiece W (S6). This stop position is a detection position of the abnormality detection sensor 90.

(7) Detection Determination of Work W In the detection position where the ascent of the work W is stopped as described above, the control unit 140 operates the abnormality detection sensor 90 or operates the abnormality detection sensor 90 in advance. FIG. 6 is a diagram showing a state at this time, and is a diagram showing a state where the abnormality detection sensor 90 detects the workpiece W at the detection position where the ascent of the workpiece W has stopped. Then, a detection signal transmitted from the abnormality detection sensor 90 is sent to the control unit 140, and the control unit 140 determines whether or not the workpiece W has been detected (S7). This determination may be performed only once. However, after it is determined that the screw hole is abnormal, the determination is made a plurality of times by waiting for a predetermined time or by raising the jig mounting base 110 and then raising it again. The work W may be detected. Further, at the detection position where the ascent of the workpiece W is stopped, the lower end of the workpiece W is detected. However, a portion other than the lower end of the workpiece W may be detected.

  Here, when the multi-threaded screw portion 101 is incompletely screwed into the screw hole W1, the workpiece W is not received by the stepped portion 103, so that the workpiece W is positioned above the detection position. In that case, there is a high possibility that the multi-threaded screw portion 101 will not be screwed in due to a problem that the screw hole W1 is not normally formed, and therefore the control unit 140 determines that the screw hole is abnormal (S8). The abnormality at this time is that the screw hole W1 itself is normal, but foreign matter such as a facet generated when the screw hole W1 is threaded or the like is caught between the multi-threaded screw portion 101 and the like. This also includes the case where does not descend to the detection position.

  On the contrary, when the multi-threaded screw portion 101 is screwed into the screw hole W1 and the workpiece W is received by the step portion 103, the workpiece W is positioned at the detection position. In this case, the control unit 140 determines that the screw hole is normal (S9).

(8) Lowering of Work W After the position detection of the work W is completed by the abnormality detection sensor 90 as described above, the work W and the inspection jig 100 are lowered (S10). At this time, the control unit 140 operates the vertical drive source 121 of the pedestal vertical mechanism 120 to lower the placement plate 30. In this lowering, the control unit 140 may operate the rotation driving source 131 of the pedestal rotation mechanism 130 to reverse the placement plate 30, but it does not have to be reverse. When the mounting plate 30 is reversely rotated, the multi-threaded screw portion 101 is smoothly removed from the screw hole W1. Further, even when the mounting plate 30 is not reversed, the multi-threaded screw portion 101 is removed from the screw hole W1 while the multi-threaded screw portion 101 is rotated with respect to the screw hole W1 due to the weight of the inspection jig 100. Become.

  FIG. 7 shows a state in which the workpiece W and the inspection jig 100 are lowered and the workpiece W is placed on the placement plate 30. As shown in FIG. 7, when the placement plate 30 is lowered by a predetermined amount, the placement plate 30 cannot be lowered any further due to the presence of the table 20. Further, the workpiece W comes into contact with the mounting plate 30, and the workpiece W is not lowered relative to the mounting plate 30. However, when the inspection jig 100 continues to reverse with respect to the workpiece W, it is possible to realize a state in which the multi-threaded screw portion 101 comes out of the screw hole W1.

  Note that when the workpiece W comes into contact with the mounting plate 30, the workpiece W rotates with inertia for a while, but immediately the workpiece W stops rotating, and thereafter, the weight of the inspection jig 100 and the mounting plate 30 are rotated. Due to the action of at least one of the rotations, the inspection jig 100 is lowered while being reversed. At this time, the lower bottom portion of the main body shaft portion 102 may be separated from the jig mounting base 110.

  When the jig mounting base 110 is lowered to the initial position below, the control unit 140 stops the operation of the vertical drive source 121. Here, when the screw hole abnormality of the screw hole W1 is detected, the control unit 140 activates not-shown notification means such as an alarm (S11). In this way, the leaving means is operated when the screw hole abnormality of the screw hole W1 is detected, there is a possibility that the life of the dedicated tap for forming the screw hole W1 has come. Is high. At this time, the control unit 140 operates the discharge drive source 81 to discharge the work W to the recovery position for abnormality. However, if it is determined that the screw hole is abnormal, the above-described detection is tried several times as well as once, and all of the determinations are determined to be screw hole abnormalities as in S8. In such a case, the workpiece W may be discharged to the recovery position for abnormality.

  Here, although the workpiece W is detected at a predetermined detection position, when the inspection jig 100 is lowered, a foreign object such as a face when a screw is cut is caught between the multi-threaded screw portion 101 and the screw hole W1. Therefore, although only the jig mounting base 110 is lowered to the initial position, the inspection jig 100 may not be lowered to the jig mounting base 110. However, whether or not the inspection jig 100 is in the initial position is detected by a detection sensor (not shown). Therefore, even when the inspection jig 100 does not descend to the jig mounting base 110, the control unit 140 activates a notification means such as an alarm (S12).

  On the other hand, when the screw hole abnormality of the screw hole W1 is not detected, the detection of the screw hole abnormality of one work W is ended. At this time, the control unit 140 operates the discharge drive source 81 to discharge the workpiece W to the normal collection position. Then, the screw hole W1 of the next workpiece W is detected.

<3. About effect>
According to the screw hole inspection device 10 and the screw hole inspection method configured as described above, the screw hole inspection device 10 includes the inspection jig 100 including the multi-threaded screw portion 101, and the inspection jig 100 is placed thereon. A jig mounting base 110 is further provided. Moreover, a pedestal vertical mechanism 120 that moves the multi-threaded screw portion 101 of the inspection jig 100 relative to the screw hole W1 is provided, and the support state of the workpiece W by the inspection jig 100 is determined by the operation of the pedestal vertical mechanism 120. This is realized, and the multi-threaded screw portion 101 is screwed into the screw hole W1 using at least the weight of the work W in the supported state. In addition, an abnormality detection sensor 90 that detects whether or not the workpiece W is located at a screwing completion position (detection position) with respect to the inspection jig 100 is provided, based on a detection signal transmitted from the abnormality detection sensor 90. It is determined whether the screw hole W1 is normal. The detection signal from the abnormality detection sensor 90 is transmitted to the control unit 140, and the control unit 140 controls the operation of the pedestal vertical mechanism 120.

  For this reason, the screw hole of the multi-thread screw can be easily and accurately used by monitoring the screwing state of the inspection jig 100 into the workpiece W using the screwing operation into the inspection jig 100 due to the weight of the workpiece W. W1 can be inspected.

  That is, in the multi-threaded screw, compared to the tap for single-threaded screw, the load at the time of thread cutting is large and the tool life is shortened. Although it is necessary to appropriately manage the life of the tap, in the inspection in which the inspection jig 100 is always forcibly rotated by a motor or the like, the inspection may be passed even if there is some processing defect. However, in the screw hole inspection apparatus 10 according to the present embodiment, when the screw hole W1 is inspected, the inspection jig 100 is used to operate the pedestal vertical mechanism 120 and the work W is dropped due to its own weight. Therefore, the screw hole W1 of the multi-threaded screw can be inspected easily and accurately.

  Further, as described above, in the inspection in which the inspection jig 100 is always forcedly rotated by a motor or the like, when the concave and convex shape of the screw hole W1 is formed by cutting with a dedicated tap, it is somewhat derived from the tool life. In many cases, it is difficult to determine whether or not the tool life has arrived even if the cutting failure occurs. On the other hand, in this embodiment, since the inspection jig 100 can be used to perform the inspection accompanied by the falling of the workpiece W due to its own weight, whether the cutting failure of the screw hole W1 resulting from the tool life has occurred. It is easy to determine whether or not the tool life of the dedicated tap has been reached.

  Moreover, in this Embodiment, the base raising / lowering mechanism 120 moves the jig | tool mounting base 110 to a perpendicular direction. At the same time, the inspection jig 100 is provided with a stepped portion 103 in which the workpiece W comes into contact with the workpiece W after the multi-threaded screw portion 101 is screwed into the screw hole W1. Then, the abnormality detection sensor 90 detects whether or not the workpiece W is located at the step portion 103 when the inspection jig 100 is located at the detection position. For this reason, it can be easily determined whether or not the multi-threaded screw portion 101 is properly screwed into the screw hole W1 based on whether or not the workpiece W is in contact with the stepped portion 103. Therefore, it is possible to accurately determine whether or not the screw hole is abnormal.

  Furthermore, in the present embodiment, the inspection jig 100 is attached to the jig mounting base 110 by fitting in an uneven shape such as the insertion hole 102a and the mounting shaft 111. In addition, in the fitting of the concave and convex shapes, the inspection jig 100 can slide in the rotation direction and the vertical direction with respect to the jig mounting base 110, and the jig mounting base 110 includes the base rotating mechanism 130. The operation is controlled by the control unit 140. For this reason, the jig mounting base 110 and the inspection jig 100 do not always rotate integrally, and the inspection jig 100 is provided to be slidable with respect to the jig mounting base 110.

  Therefore, since the inspection jig 100 does not always rotate integrally with the jig mounting base 110, the multi-threaded screw portion 101 is not always forcedly screwed into the screw hole W1, and therefore the workpiece W It is screwed into the screw hole W1 in a state accompanied by a drop due to its own weight. Therefore, it is possible to inspect the screw hole W1 of the multi-thread screw.

  In the present embodiment, the control unit 140 controls the operation of the pedestal rotation mechanism 130 so that the inspection jig 100 and the jig mounting base 110 are reversed in the screw hole W1 of the workpiece W. The operation of the pedestal vertical mechanism 120 is controlled so that the multi-thread screw portion 101 is brought into contact with the screw hole W1 of the work W placed on the placement plate 30 as it is. For this reason, it is possible to align the multi-threaded screw portion 101 and the screw hole W1, and the multi-threaded screw portion 101 can be screwed into the screw hole W1 with high accuracy.

  Further, after bringing the multi-threaded screw portion 101 into contact with the screw hole W1, the control unit 140 controls the operation of the pedestal rotation mechanism 130 so that the jig mounting pedestal 110 performs the forward rotation opposite to the reverse rotation. The workpiece W is lifted by the inspection jig 100 by controlling the operation of the pedestal vertical mechanism 120 so as to raise the jig mounting base 110 and the inspection jig 100 in the normal rotation state. For this reason, it is possible to easily realize a state in which the multi-threaded screw portion 101 is screwed into the screw hole W1 in a state where the workpiece W is dropped due to its own weight.

  In addition, when the inspection jig 100 is positioned at the detection position, the control unit 140 controls the operation of the base vertical mechanism 120 so as to stop the ascent of the jig mounting base 110 and the inspection jig 100, and in that state The presence / absence of the workpiece W is detected using the abnormality detection sensor 90. For this reason, by detecting the presence or absence of the workpiece W by the abnormality detection sensor 90, it is possible to accurately determine whether or not the screw hole is abnormal. Further, after the detection by the abnormality detection sensor 90, the operation of the pedestal vertical mechanism 120 is controlled so that the jig mounting base 110 and the inspection jig 100 are lowered. Therefore, the work W is placed on the placement plate 30, and the screwing of the multi-threaded screw portion 101 can be removed from the screw hole W1 by further lowering the jig mounting base 110 and the inspection jig 100. That is, even when unscrewing the multi-threaded screw portion 101 from the screw hole W1, the workpiece W can be easily removed using its own weight.

<4. Modification>
As mentioned above, although each embodiment of this invention was described, this invention can be variously deformed besides this. This will be described below.

  In the above-described embodiment, the placement plate 30 is exemplified and described as the placement portion on which the workpiece W is placed. However, the placement unit is not limited to the placement plate 30. For example, the table 20 may correspond to the placement unit. In this case, a configuration in which the mounting plate 30 and the guide mechanism 40 are omitted may be employed. In addition, when employ | adopting the structure which abbreviate | omits the mounting plate 30 and the guide mechanism 40, it also becomes a structure which also omits the plate raising / lowering mechanism 50 as shown in FIG. Further, when the table 20 corresponds to the placement portion, the insertion hole 21 corresponds to the insertion portion.

  In the above-described embodiment, a configuration in which the inspection jig 100 is brought into contact with and separated from the workpiece W by using the pedestal vertical mechanism 120 is employed. However, other configurations may be adopted as long as the inspection jig 100 and the workpiece W are relatively close to each other. As another configuration, for example, a mechanism for moving the workpiece W while disabling the inspection jig 100 may be provided, and a mechanism for moving the workpiece W against and away from the inspection jig 100 may be used. A mechanism for moving the workpiece W may be provided to move both the inspection jig 100 and the workpiece W. Further, the mechanism for moving the workpiece W may be a mechanism for moving the table 20 up and down, or a structure in which the amount of movement in the vertical direction between the guide mechanism 40 and the plate vertical mechanism 50 is increased.

  In the above-described embodiment, the abnormality detection sensor 90 detects the position where the workpiece W is in contact with the stepped portion 103. However, when the workpiece W is located at a position higher than the stepped portion 103 due to an abnormality in the screw hole of the workpiece W, the abnormality detection sensor is at a height that assumes that the workpiece W is positioned when the screw hole is abnormal. The workpiece W may be detected using 90.

  Moreover, in the above-mentioned embodiment, although the structure which provides the base rotation mechanism 130 is employ | adopted, the structure which abbreviate | omits this base rotation mechanism 130 may be employ | adopted.

  In the above-described embodiment, the inspection jig 100 includes the insertion hole 102a, and the inspection jig 100 is attached to the jig mounting base 110 by inserting the attachment shaft 111 into the insertion hole 102a. It is attached. However, the attachment of the inspection jig 100 to the jig mounting base 110 is not limited to this. For example, a convex part is formed on the inspection jig 100 side, a concave part is formed on the jig mounting base 110 side, and the inspection jig 100 is attached to the jig mounting base 110 by fitting these concave and convex shapes. You may do it.

DESCRIPTION OF SYMBOLS 10 ... Screw hole inspection apparatus, 20 ... Table, 21 ... Insertion hole, 22 ... Guide cylinder part, 30 ... Mounting plate (corresponding to mounting part), 31 ... Insertion hole (corresponding to insertion part), 32 ... Guide shaft , 40 ... Guide mechanism, 50 ... Plate up / down mechanism, 51 ... Plate drive source, 60 ... Clamp mechanism, 61 ... Clamp drive source, 70 ... Work transfer mechanism, 71 ... Transport drive source, 80 ... Work discharge mechanism, 81 DESCRIPTION OF SYMBOLS ... Drive source for discharge, 90 ... Abnormality detection sensor (corresponding to detection means), 100 ... Inspection jig, 101 ... Multi-threaded screw portion, 102 ... Main body shaft portion, 102a ... Insertion hole, 103 ... Stepped portion, 104 ... Guide part, 105 ... Screw chamfering part, 106 ... Flange part, 110 ... Jig mounting base, 111 ... Mounting shaft, 120 ... Base vertical mechanism (corresponding to the moving mechanism), 121 ... Vertical driving source, 130 ... Base rotating mechanism, 31 ... rotational driving source, 140 ... control unit (corresponding to control means), W ... workpiece, W1 ... screw hole

Claims (5)

A screw hole inspection device for inspecting a screw hole of a multi-thread screw formed in a workpiece,
A work part is placed, and a placement part having an insertion part that communicates with the screw hole;
An inspection jig comprising a multi-threaded screw portion screwed into the screw hole of the workpiece through the insertion portion;
A jig mounting base on which the inspection jig is placed;
The multi-threaded screw portion of the inspection jig is moved relative to the screw hole to realize a support state of the work by the inspection jig, and at least the weight of the work is used in the support state. A moving mechanism for screwing the multi-threaded screw portion into the screw hole;
Detecting means for detecting whether or not the workpiece is located at a screwing completion position with respect to the inspection jig;
Control means for determining whether the screw hole is normal based on a detection signal transmitted from the detection means, and for controlling the operation of the moving mechanism;
A screw hole inspection device comprising: The moving mechanism moves the jig mounting base vertically upward,
The inspection jig is provided with a stepped portion for positioning the workpiece by contacting the workpiece when the multi-threaded screw portion is completely screwed into the screw hole,
The detecting means detects whether the workpiece is positioned at the stepped portion when the inspection jig is positioned at a detection position;
The screw hole inspection device according to claim 1. The inspection jig is attached to the jig mounting base by fitting in an uneven shape, so that the inspection jig can slide in the rotation direction and the vertical direction with respect to the jig mounting base. And
The jig mounting base is provided with a base rotating mechanism whose rotational operation is controlled by the control means.
The screw hole inspection apparatus according to claim 2. The control means includes
Controlling the operation of the moving mechanism so that the multi-threaded screw portion is brought into contact with the screw hole of the workpiece placed on the placing portion,
After the contact, the operation of the moving mechanism is controlled so as to raise the jig mounting base and the inspection jig, and the workpiece is lifted by the inspection jig,
When the inspection jig is located at the detection position, it is detected whether or not the workpiece is located at the screwing completion position,
The operation of the moving mechanism is controlled so as to lower the jig mounting base and the inspection jig, and the workpiece is placed on the mounting portion, and the jig mounting base and the inspection jig are further lowered. Unscrew the multi-threaded screw portion from the screw hole by
The screw hole inspection device according to claim 3. A screw hole inspection method for inspecting a screw hole of a multi-threaded screw formed on a workpiece using an inspection jig,
The inspection jig is provided and a multi-threaded screw portion to be screwed into the screw hole of the work is moved relative to the screw hole to realize a support state of the work by the inspection jig, A screwing step of screwing the multi-threaded screw portion into the screw hole by utilizing at least the weight of the workpiece in the supporting state;
A detection step of detecting whether or not the workpiece is located at a screwing completion position with respect to the inspection jig;
A determination step of determining whether or not the screw hole is normal based on a detection signal transmitted from the detection step;
A screw hole inspection method comprising:

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