JP6305204B2 - Fastener - Google Patents

Description

  The present invention relates to a fastener, and more particularly to a fastener that holds a nut and washer with a holding tool.

  The attachment of a mating member to a predetermined attachment member via bolts and nuts is widely performed. That is, for example, the bolt hole of the mounting member and the bolt hole of the mating member are overlapped and communicated, and after passing one bolt through these bolt holes, a nut is screwed into the screw portion of the bolt protruding from the bolt hole. Match. A washer may be interposed between the nut and the mating member or mounting member.

  When a sufficient tightening torque is obtained between the nut and the bolt, a tightening tool such as a nut runner is used. That is, the nut is accommodated in the socket and is screwed together with the socket. In addition, when using a washer, as described in Patent Documents 1 and 2, a nut and a washer are simultaneously held by a socket.

  In this case, the socket has a so-called double cylinder structure of an inner socket and an outer socket. Patent Document 1 proposes a configuration that makes it easy to hold a nut with an inner socket and hold a washer with an outer socket even when a phase shift occurs between the nut and the washer.

  Further, in Patent Document 2, when a nut is screwed into a screw portion of the bolt, the washer receives the reaction force of the rotating tool in order to prevent the bolt from rotating due to the rotational force of the screwing nut. A configuration is disclosed.

JP 2012-125874 A JP 2012-125910 A

  If a washer is used, it may be necessary to phase the washer and bolt prior to screwing the nut. Patent Documents 1 and 2 do not describe this phase alignment. As a result, it is difficult for the techniques described in Patent Documents 1 and 2 to cope with the phase alignment.

  The present invention has been made to solve the above-described problems, and provides a fastener that can easily match the phase of a washer held together with a nut and the phase of a bolt screwing the nut. With the goal.

In order to achieve the above object, the present invention provides a fastening tool comprising a nut that is screwed into a threaded portion of a bolt and a holding tool that is passed through the bolt and is pressed from the nut. There,
A socket in which a pocket for accommodating the nut is formed;
A plurality of washer holding members held in the socket and swinging in a direction approaching or separating from the opening of the pocket;
A resilient member for resiliently biasing the washer holding member toward the socket;
Comprising
A step portion into which a part of the side peripheral wall of the washer enters is depressed in the washer holding member,
The washer holding member has a flange portion that enters between the nut housed in the pocket and the washer in which a part of the side peripheral wall has entered the stepped portion, and separates the nut and the washer. Have
The washer holding member swings in a direction away from the opening of the pocket when the nut is screwed into the threaded portion, and the flange portion is detached from between the nut and the washer. .

  That is, in the present invention, the washer held by the washer holding member and the nut held by the socket are separated by the flange portion of the washer holding member. For this reason, the operation | work which phase-matches a washer and a volt | bolt and the operation | work which screws a nut to a volt | bolt can be performed separately. In other words, it becomes easy to match the phase of the washer with the phase of the bolt to which the nut is screwed.

  Note that the washer holding member swings after the washer and the bolt are phased. That is, the collar part is detached from between the nut and the washer. For this reason, it is easy to screw the nut onto the bolt and to press the end face of the nut against the washer. Eventually, a predetermined tightening torque can be obtained between the nut and the bolt, and sufficient connection strength can be provided between the members.

The flange portion of the washer retaining member that is thinner in a tapered shape as it approaches the nut and washer. In this case, it becomes easy for the flange portion to be separated from between the nut and the washer. Therefore, the washer holding member easily swings.

  Moreover, it is preferable that the site | part in which the step part was depressed and formed of the washer holding member is hollow. In this case, since the said part is lightweight, the drag with respect to rocking | fluctuation becomes small. For this reason, it becomes much easier that the collar part of the washer holding member is separated from the side peripheral wall of the washer, that is, the washer holding member is swung.

  A magnet for attracting and holding the nut may be provided in the pocket. As a result, the nut is prevented from falling out of the pocket, and the operation of screwing the nut becomes easy.

  In addition to the above, it is preferable that the fastening tool is configured by further providing a rotating shaft to which the socket is attached and a rotation urging means for rotating the rotating shaft. In this case, the phase alignment of the washer and the bolt and the screwing of the nut to the bolt can be automatically advanced.

  In this case, it is preferable to provide a resilient means for resiliently biasing the socket in a direction away from the rotating shaft. This is because it is easy to advance the socket after the washer is positioned and fixed, and thus to advance while rotating the nut.

  According to the present invention, the washer holding member holds the washer and the socket holds the nut, and the flange portion of the washer holding member is interposed between the washer and the nut. Since the washer and the nut are separated from each other by this intervention, the work of phase matching the washer and the bolt and the work of screwing the nut to the bolt can be performed separately. In other words, it becomes easy to match the phase of the washer with the phase of the bolt to which the nut is screwed.

  Since the washer holding member can be swung, if the washer holding member is swung after the phasing of the washer and the bolt is finished and the collar part is detached from between the nut and the washer, the nut is further screwed. Can do. For this reason, it is easy to screw the nut onto the bolt and to press the end face of the nut against the washer. Therefore, a predetermined tightening torque can be obtained between the nut and the bolt, and as a result, sufficient connection strength can be provided between the members.

It is a schematic perspective view when connecting a 1st member and a 2nd member with a stud bolt (bolt) and a hexagon cap nut (nut). FIG. 2A is a front view of a principal part showing a state in which the phases of the vertex of the hexagonal flange portion of the stud bolt and the vertex of the hexagonal insertion hole of the washer are matched, and FIG. 2B is a diagram of the hexagonal flange portion of the stud bolt. It is a principal part front view which shows the state which the phase shift produced between the vertex and the vertex of the hexagonal insertion hole of a washer. It is a front view of the holding tool which comprises the fastener concerning embodiment of this invention. FIG. 4 is a cross-sectional view taken along line IV-IV in FIG. 3. It is principal part side surface sectional drawing which shows the state which passed the 2nd thread part of the said stud bolt through the hexagonal insertion hole of the washer hold | maintained at the washer holding claw (washer holding member). FIG. 6 is a side cross-sectional view of the main part showing a state in which the inner wall of the hexagonal insertion hole of the washer is in contact with the hexagonal flange portion of the stud bolt when the washer is advanced from FIG. 5. It is principal part side surface sectional drawing which shows the state by which the phase alignment of the said hexagonal flange part and the said washer was complete | finished, and the said hexagonal flange part was inserted in the said hexagonal insertion hole. FIG. 8 is a side cross-sectional view of the main part showing a state where the washer holding claw starts swinging when the nut is advanced from FIG. 7. It is principal part side surface sectional drawing which shows the state which the nut further advanced from FIG. 8 and the flange part contact | abutted to the end surface of the washer.

  DESCRIPTION OF EMBODIMENTS Hereinafter, preferred embodiments of a fastener according to the present invention will be described and described in detail with reference to the accompanying drawings.

  First, the phase alignment of washers and bolts will be described. FIG. 1 is a schematic perspective view when the first member 10 and the second member 12 are connected by a stud bolt 14 (bolt) and a hexagonal cap nut 16 (nut). In this case, the first screw portion 17 of the stud bolt 14 is screwed into the first member 10 in advance, and the second screw portion 18 is passed through the bolt hole 20 formed through the second member 12. . The hexagonal cap nut 16 is screwed into the second screw portion 18 protruding from the bolt hole 20.

  In this case, the stud bolt 14 is provided with a hexagonal flange portion 22 on the starting end side of the second screw portion 18. The hexagonal flange portion 22 is also exposed from the bolt hole 20 of the second member 12. The exposed hexagonal flange portion 22 is inserted into a hexagonal insertion hole 26 formed through the washer 24. The hexagonal insertion hole 26 and the hexagonal flange portion 22 are both regular hexagons, and the opening area of the hexagonal insertion hole 26 is set slightly larger than the outer dimension of the hexagonal flange portion 22.

  When a sufficient tightening torque is obtained between the second screw portion 18 and the hexagon cap nut 16, both the hexagon cap nut 16 and the washer 24 are held by a socket such as a nut runner. At this time, it goes without saying that the hexagonal cap nut 16 is disposed on the back side and the washer 24 is disposed on the front side in the socket pocket.

  And while rotating the rotating shaft of a nut runner, a socket is made to approach the 2nd screw part 18, and while passing the 2nd screw part 18 through the hexagonal insertion hole 26 of the washer 24, the screw part of the hexagonal bag nut 16 is made into the 2nd screw part. 18 is screwed. The end face of the flange portion 28 of the hexagon cap nut 16 is finally seated on the end face of the washer 24.

  Here, when the second screw portion 18 is passed through the hexagon insertion hole 26, as shown in FIG. 2A, when the positions of the vertices of the hexagon insertion hole 26 and the hexagon flange portion 22 match, the hexagon flange portion 22 is It is easily inserted into the hexagon insertion hole 26. On the other hand, as shown in FIG. 2B, when the positions of the vertices of the hexagonal insertion hole 26 and the hexagonal flange portion 22 do not match, the end surface of the washer 24 comes into contact with the end surface of the hexagonal flange portion 22. Is blocked. When the hexagonal cap nut 16 is screwed in this state, the washer 24 is sandwiched between the hexagonal flange portion 22 and the hexagonal cap nut 16.

  In this case, the hexagon cap nut 16 cannot be further screwed. That is, the hexagon cap nut 16 stops in the middle of screwing. For this reason, it is difficult to obtain a tightening torque.

  The fastening tool according to the present embodiment rotates the washer 24 in FIG. 2A when the positional deviation (phase deviation) shown in FIG. It is possible to perform the state shown, ie, phase alignment. Hereinafter, this point will be described in detail.

  FIG. 3 is a front view of the holding tool 30 constituting the fastening tool according to the present embodiment, and FIG. 4 is a cross-sectional view taken along the line IV-IV in FIG. The holding tool 30 includes a socket 32 that holds the hexagonal cap nut 16 and a plurality of washer holding claws 34 (washer holding members) held on the outer peripheral wall of the socket 32. In the present embodiment, six washer holding claws 34 are provided. Further, in FIG. 3, one of the washer holding claws 34 is indicated by an imaginary line in order to clarify the position of a storage groove 36 to be described later.

  The socket 32 includes a cup portion 40 in which a pocket 38 is formed, and a small-diameter cylindrical shaft portion 42 (see FIG. 4) protruding from the closed end portion of the cup portion 40. The hexagonal cap nut 16 is held in the socket 32 by being accommodated in the pocket 38 of the cup portion 40.

  Six magnets 44 are embedded in the bottom wall of the pocket 38 so as to be spaced apart from each other at substantially equal intervals. These magnets 44 are magnetically attached to the dome-shaped end face of the hexagon cap nut 16. In other words, the hexagonal cap nut 16 is attracted and held by the magnet 44, and therefore it is difficult to drop off from the pocket 38.

  On the outer wall of the cup portion 40, there are formed six accommodation grooves 36 extending along the axial direction of the cup portion 40 and recessed from the outer wall of the cup portion 40 toward the inner wall side (see FIG. 3). Most of the washer holding claws 34 are inserted into the receiving grooves 36.

  In the cup portion 40, a ring-shaped bracket 46 that covers substantially half of the housing groove 36 in the axial direction is fitted on an end portion close to the cylindrical shaft portion 42. The ring-shaped bracket 46 is connected to the cup portion 40 with a bolt (not shown), thereby preventing the ring-shaped bracket 46 from dropping from the cup portion 40.

  A notch 48 (see FIG. 4) that is wider than the receiving groove 36 is formed at the tip of the cup portion 40. The tip of the washer holding claw 34 enters the notch 48.

  The washer holding claw 34 has a long body portion 50. An arcuate bulged portion 52 having an arcuate surface is provided integrally with the barrel portion 50 at the end of the barrel portion 50 while bulging while being curved outward in the diameter direction of the barrel portion 50. The side wall of the largest diameter portion of the arcuate bulging portion 52 is in point contact with the bottom wall of the housing groove 36 and the inner wall of the ring-shaped bracket 46.

  The washer holding claws 34 are not in contact with the socket 32 or the ring-shaped bracket 46 except for this point contact (not subjected to restraint). For this reason, the washer holding claw 34 can swing in a direction indicated by an arrow in FIG. 4 with a portion that makes point contact with the bottom wall of the housing groove 36 and the inner wall of the ring-shaped bracket 46 as a fulcrum. .

  The washer holding claw 34 further includes a flange portion 54 that is continuous with the body portion 50 and a cylindrical portion 56 that is continuous with the flange portion 54 and is formed hollow for weight reduction. The flange portion 54 and the cylindrical portion 56 enter the notch 48 of the cup portion 40 as described above.

  The vicinity of the outer peripheral wall of the flange portion 54 is chamfered in a tapered shape. For this reason, the wall thickness of the collar part 54 becomes small as it approaches the hexagonal cap nut 16 and the washer 24. In other words, the flange 54 is thinned in a tapered shape as it approaches the hexagonal cap nut 16 and the washer 24.

  The cylindrical portion 56 has a shape in which a side peripheral wall is notched, and therefore, an annular stepped portion 58 (stepped portion) is formed that is recessed inward in the diameter direction. The side peripheral wall of the washer 24 enters the annular step 58 of each washer holding claw 34.

  The ring-shaped bracket 46 is provided with six spring holding portions 60 so as to protrude outward in the diameter direction. Each spring holding portion 60 is formed with a holding hole 62 penetrating along the diameter direction of the cup portion 40, and a first coil spring 64 as a resilient member is accommodated in the holding hole 62.

  A bolt stop hole 66 is connected to the holding hole 62. When the bolt stop hole 66 is closed by the retaining bolt 68, the first coil spring 64 is prevented from coming off from the holding hole 62, and the first coil spring 64 is contracted. The contracted first coil spring 64 always urges and urges the body portion 50 of the washer holding claw 34 toward the bottom wall side (the pocket 38 side) of the housing groove 36. This bullet urging prevents the washer holding claw 34 from swinging when no external force is applied to the washer holding claw 34.

  The holding tool 30 configured as described above is used by being attached to, for example, a rotation shaft (none of which is shown) of a nut runner. That is, the cylindrical shaft portion 42 of the socket 32 is formed with a sliding hole 70 having a substantially square cross section and a bottom, and a tooth portion 72 is formed on the inner wall of the sliding hole 70. The tooth portion formed on the outer wall of the quadrangular columnar portion, which is the tip of the rotating shaft, meshes with the tooth portion 72. Further, the cylindrical shaft portion 42 and the quadrangular columnar portion are surrounded by a second coil spring 74 (bounce means) held on the rotating shaft. That is, the holding tool 30 is held on the rotating shaft by the meshing and the engagement of the second coil spring 74 with the cylindrical shaft portion 42. By this holding, the holding tool 30 is attached to the rotating shaft to constitute a nut runner as a fastening tool.

  The socket 32 and the rotating shaft can cause relative sliding. Further, the second coil spring 74 elastically urges the holding tool 30 in a direction away from the rotation shaft.

  The nut runner includes a rotation motor (not shown) as rotation urging means. The rotating shaft rotates under the action of the rotating motor. Of course, following the rotation of the rotating shaft, the holding tool 30 attached to the tip of the rotating shaft also rotates.

  The fastener according to the present embodiment is basically configured as described above. Next, the function and effect will be described.

  When the holding tool 30 is attached to the rotating shaft, a nut runner as a fastening tool is configured. Using this nut runner, the washer 24 is passed through the second threaded portion 18 of the stud bolt 14 shown in FIG. Of course, the second screw portion 18 of the stud bolt 14 is passed through the bolt hole 20 of the second member 12 in advance.

  Then, the hexagonal cap nut 16 is inserted into the pocket 38 of the holding tool 30. The dome-shaped end surface of the hexagonal cap nut 16 is attracted and held by a magnet 44 provided on the bottom wall of the pocket 38. For this reason, there is no concern that the hexagonal cap nut 16 is detached from the pocket 38.

  Next, a part of the side peripheral wall of the washer 24 is caused to enter the annular step portion 58 of the washer holding claw 34. For this purpose, the operator pushes up at least one washer holding claw 34 with a finger or the like against the spring urging force of the spring coil, and puts the washer 24 on the annular step 58 of the remaining washer holding claw 34. Insert the peripheral wall. Thereafter, when the finger or the like is released from the pushed-up washer holding claw 34, the washer holding claw 34 is elastically biased from the first coil spring 64. As a result, the cylindrical portion 56 and the flange portion 54 swing toward the opening side of the pocket 38.

  The cylindrical portion 56 and the flange portion 54 enter the notch 48 at the tip of the socket 32. At this time, a part of the side peripheral wall of the washer 24 is inserted into the annular stepped portion 58, and the state shown in FIGS. After all, the washer 24 is held by the washer holding claw 34 by inserting the side peripheral wall into the annular stepped portion 58 of the six washer holding claws 34.

  Between the hexagonal cap nut 16 accommodated in the pocket 38 and the washer 24 held by the washer holding claw 34, a flange 54 of the washer holding claw 34 is interposed. For this reason, the hexagon cap nut 16 and the washer 24 are separated by a distance corresponding to the thickness of the flange 54.

  Thus, after the holding tool 30 holds the hexagonal cap nut 16 and the washer 24, the rotating motor is energized. Along with this, the rotation shaft and the holding tool 30 start to rotate. Further, the rotating shaft and the holding tool 30 advance toward the stud bolt 14 (see FIG. 4).

  When the holding tool 30 moves forward, first, the second screw portion 18 of the stud bolt 14 passes through the hexagonal insertion hole 26 of the washer 24 as shown in FIG. At this time, even if the inner wall of the hexagonal insertion hole 26 of the washer 24 comes into contact with the side peripheral wall of the second screw portion 18, the washer 24 is blocked by the flange portion 54 of the washer holding claw 34. Therefore, it is avoided that the washer 24 is retracted toward the hexagonal cap nut 16 side.

  When the holding tool 30 further advances, the second screw portion 18 of the stud bolt 14 starts to be screwed into the screw portion inside the hexagonal cap nut 16 as shown in FIG. On the other hand, the washer 24 reaches the hexagon flange portion 22 of the stud bolt 14. Here, when the position of the apex of the hexagonal insertion hole 26 of the washer 24 and the position of the apex of the hexagonal flange portion 22 do not match, that is, when the phase shift state shown in FIG. The inner wall comes into contact with the hexagon flange portion 22. For this reason, the forward movement and rotation of the washer 24 are temporarily stopped.

  As the inner wall of the hexagonal insertion hole 26 abuts against the hexagonal flange portion 22, the washer 24 receives a reaction force from the stud bolt 14. By this reaction force, the washer 24 comes into press contact with the flange portion 54. A frictional force is generated between the flange 54 and the washer 24 that have received this pressing. For this reason, the rotational urging force acting on the rotary shaft and the holding tool 30 is transmitted to the washer 24 as a rotational torque via the washer holding claw 34.

  The washer 24 having received the rotational torque rotates with the inner wall of the hexagonal insertion hole 26 in contact with the hexagonal flange portion 22. During this rotation, the position of the vertex of the hexagonal insertion hole 26 matches the position of the vertex of the hexagonal flange portion 22. That is, the phase alignment shown in FIG. 2A is performed. As a result, the washer 24 advances, and the hexagonal flange portion 22 enters the hexagonal insertion hole 26, resulting in the state shown in FIG.

  Since the hexagonal flange portion 22 has entered the hexagonal insertion hole 26, the washer 24 cannot advance or rotate. That is, the washer 24 is positioned and fixed and phased. In addition, since the flange portion 54 of the washer holding claw 34 is interposed between the washer 24 and the hexagonal cap nut 16, the holding tool 30 cannot be moved forward.

  On the other hand, the rotation urging force of the rotation motor acts on the holding tool 30. For this reason, the rotation of the holding tool 30 is maintained. At this time, since the hexagonal cap nut 16 accommodated in the pocket 38 of the socket 32 also rotates, the screwing of the hexagonal cap nut 16 to the second screw portion 18 of the stud bolt 14 continues. Accordingly, only the hexagonal cap nut 16 moves forward. At this time, the front end surface of the quadrangular columnar portion of the rotating shaft comes into contact with the bottom wall of the sliding hole 70.

  As the hexagonal cap nut 16 advances, the flange portion 28 of the hexagonal cap nut 16 approaches the washer 24 that is positioned and fixed. That is, the distance between the two becomes small. Therefore, a force in the direction from the hexagonal cap nut 16 toward the washer 24 and a force in the direction from the washer 24 toward the hexagonal cap nut 16 act on the flange portion 54 of the washer holding claw 34.

  The washer holding claw 34 that has received these forces on the flange 54 has the largest diameter portion of the arcuate bulged portion 52 in point contact with the bottom wall of the housing groove 36 and the inner wall of the ring-shaped bracket 46 as a fulcrum. As shown in FIG. 8, it begins to swing in a direction away from the opening of the pocket 38. That is, the flange 54 starts to be detached from between the hexagonal cap nut 16 and the washer 24. Since the flange portion 54 is thinned in a taper shape toward the outer side in the diameter direction, the separation, in other words, the swing of the washer holding claw 34 easily proceeds.

  Moreover, the cylindrical part 56 is hollow and is lightweight for this reason. Therefore, since the center of gravity of the washer holding claw 34 is located away from the cylindrical portion 56, the cylindrical portion 56 can easily swing.

  As the washer holding claw 34 swings, the first coil spring 64 is compressed by the body portion 50 of the washer holding claw 34. Further, the holding tool 30 moves forward by the elastic biasing force of the second coil spring 74. At this time, the tooth portion 72 in the sliding hole 70 slides along the tooth portion of the quadrangular columnar portion of the rotating shaft. As a result, the front end surface of the square columnar part is separated from the bottom wall of the sliding hole 70.

  As the hexagonal cap nut 16 further advances, as shown in FIG. 9, the washer holding claw 34 further swings and the flange portion 54 is detached from between the hexagonal cap nut 16 and the washer 24, and the washer 24 or hexagonal It rides on the side peripheral wall of the flange portion 28 of the cap nut 16. Therefore, the hexagonal cap nut 16 is not blocked from the flange portion 54 of the washer holding claw 34. For this reason, the holding tool 30 receives the elastic biasing force of the second coil spring 74 and further advances while rotating. As a result, the dome-shaped end portion of the hexagonal cap nut 16 is attracted again to the magnet 44, and as a result, the rotational torque transmitted to the hexagonal cap nut 16 increases.

  For the above reasons, the screwing of the hexagonal cap nut 16 to the second screw portion 18 further proceeds. When the screwing of the hexagonal cap nut 16 is finished, the flange portion 28 of the hexagonal cap nut 16 is pressed against the washer 24. In other words, the washer 24 is pressed from the hexagonal cap nut 16, and a sufficient tightening torque is obtained between the second screw portion 18 of the stud bolt 14 and the hexagonal cap nut 16.

  Thus, by providing the holding tool 30 with the washer holding claws 34 provided in the socket 32, it is easy to perform phase alignment of the washer 24 and the stud bolt 14. For this reason, the hexagonal cap nut 16 can be easily screwed into the second screw portion 18 of the stud bolt 14 with the washer 24 interposed. Thus, the first member 10 and the second member 12 are connected by the stud bolt 14 and the hexagonal cap nut 16.

  When the screwing of the hexagonal cap nut 16 to the second screw portion 18 is completed, the rotating shaft and the holding tool 30 are retracted. At this time, the hexagonal cap nut 16 is exposed from the inside of the pocket 38 and detached from the socket 32. Then, the body portion 50 of the washer holding claw 34 receives the elastic urging force from the second coil spring 74, and thereby, the collar portion 54 and the cylindrical portion 56 swing so as to face the opening side of the pocket 38. Of course, the fulcrum in this case is also the point contact point. As shown in FIG. 4, the flange portion 54 and the cylindrical portion 56 enter the notch 48 of the cup portion 40.

  The present invention is not particularly limited to the above-described embodiment, and various modifications can be made without departing from the gist of the present invention.

  For example, the insertion hole of the washer 24 may be a circular hole, or a hexagonal nut or the like may be screwed in place of the hexagonal cap nut 16.

  Further, the holding tool 30 may be attached to a torque wrench or the like to constitute a fastening tool.

DESCRIPTION OF SYMBOLS 10 ... 1st member 12 ... 2nd member 14 ... Stud bolt 16 ... Hexagon cap nut 17, 18 ... Screw part 20 ... Bolt hole 22 ... Hex flange part 24 ... Washer 26 ... Hex insertion hole 30 ... Holding tool 32 ... Socket 34 ... Washer holding claw 36 ... Accommodating groove 38 ... Pocket 44 ... Magnet 50 ... Body part 52 ... Arc-shaped bulging part 54 ... Bridge part 56 ... Cylindrical part 58 ... Annular step part 64 ... First coil spring 74 ... Second coil spring

Claims (5)

A fastening tool comprising a holding tool for holding a nut screwed into a screw portion of a bolt and a washer that is passed through the bolt and pressed from the nut,
A socket in which a pocket for accommodating the nut is formed;
A plurality of washer holding members held in the socket and swinging in a direction approaching or separating from the opening of the pocket;
A resilient member for resiliently biasing the washer holding member toward the socket;
Comprising
A step portion into which a part of the side peripheral wall of the washer enters is depressed in the washer holding member,
The washer holding member has a flange portion that enters between the nut housed in the pocket and the washer in which a part of the side peripheral wall has entered the stepped portion, and separates the nut and the washer. Have
The flange is thinned in a tapered shape as it approaches the nut and the washer,
The washer holding member swings in a direction away from the opening of the pocket when the nut is screwed into the threaded portion, and the flange portion is detached from between the nut and the washer. Fastener. In claim 1 Symbol with mounting fasteners, fasteners, characterized in that the washer holding member, portions that the stepped portion is recessed formation is hollow. 3. The fastener according to claim 1 or 2 , wherein a magnet for attracting and holding the nut is disposed in the pocket. The fastener according to any one of claims 1 to 3 , further comprising: a rotating shaft to which the socket is attached; and a rotation urging unit that rotates the rotating shaft. 5. The fastener according to claim 4 , further comprising a resilient means for resiliently urging the socket in a direction away from the rotating shaft.

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