CN210093852U - Wire bending clamp mechanism - Google Patents

Abstract

The application relates to a wire bending clamp mechanism which comprises a driving piece, a movable base, a cylindrical pressing wheel, a pushing block and a guide track plate, wherein the movable base is connected to the driving piece in a transmission manner; the cylindrical pinch roller is arranged on the movable base and is connected to the movable base in a sliding manner; the push block is fixed on the movable base, is arranged opposite to the cylindrical pinch roller and is spaced by a preset distance; the guide rail plate is provided with a guide groove, at least part of the cylindrical pressing wheel is contained in the guide groove and moves in the guide groove along with the movement of the moving base, the cylindrical pressing wheel has a trend of moving towards the direction far away from the push block when moving in the guide groove, the guide groove comprises a first guide groove and a second guide groove, the first guide groove and the second guide groove are communicated with each other, and different depths are provided to form a stepped structure. The cable can be taken out after the cable is buckled in curved line anchor clamps mechanism, and taking out of cable is comparatively convenient, at the in-process that resets of ejector pad and cylinder pinch roller, the cable has taken out, can reverse line ball, and the line ball effect is better.

Description

Wire bending clamp mechanism

Technical Field

The present application relates to machining structures, and more particularly to a wire bending fixture mechanism.

Background

When welding the cable to the circuit board, if fix the cable to the circuit board earlier, it is fixed to weld tin again, both can get better fixed effect, can realize firm electricity again and connect. The cable is fixed on the circuit board and needs to be bent, the cable is manually penetrated through a through hole in a workpiece in the traditional mode, and then the cable is manually bent, however, the manual mode is low in efficiency, and the copper wire of the cable has large damage to the hand of a user in the bending process. Also have through automatic or semi-automatization's curved line mechanism, with the work piece fixed back, bend the cable from the work piece both sides, however, traditional automatic or semi-automatization's curved line is after the curved line is accomplished, and curved line mechanism need roll back, if not in time take out, curved line mechanism rolls back the in-process and can reverse line ball, influences curved line effect. Therefore, the traditional automatic or semi-automatic wire bending mechanism has the disadvantages that reverse wire pressing is caused because the cable is inconvenient to take out after being bent, and the wire bending effect is not ideal.

SUMMERY OF THE UTILITY MODEL

Therefore, the wire bending clamp mechanism is needed to solve the problems that the traditional automatic or semi-automatic wire bending mechanism is inconvenient to take out after the cable is bent, reverse wire pressing is caused, and the wire bending effect is not ideal.

A wire bending clamp mechanism comprises a driving piece, a movable base, a cylindrical pinch roller, a push block and a guide track plate, wherein,

the movable base is in transmission connection with the driving piece;

the cylindrical pinch roller is arranged on the movable base and is connected to the movable base in a sliding manner;

the push block is fixed on the movable base, is arranged opposite to the cylindrical pinch roller and is spaced by a preset distance, and the cylindrical pinch roller and the push block move along with the movement of the movable base;

be provided with the guide way on the direction track board, the cylinder pinch roller is partial at least accept in the guide way, and follow the removal of moving the base is in the guide way removes, the cylinder pinch roller is in when the guide way removes, have to keeping away from the trend that the direction of ejector pad removed, the guide way includes first guide way and second guide way, first guide way with the second guide way communicates each other, and has different degree of depth in order to form the echelonment structure.

In one embodiment, the mobile base further comprises a housing, wherein a cavity is arranged in the housing, and the mobile base is arranged in the cavity;

the dustcoat includes bottom plate, a plurality of curb plates and roof, a plurality of curb plates along the edge of bottom plate sets up to each other fixed connection surrounds and forms the cavity, the roof reaches direction track board fixed connection in the curb plate, and the lid fits the cavity the roof with reserve between the direction track board and have predetermined clearance, form the slide, the slide with the guide way intercommunication under the drive of moving the base, the ejector pad reaches the cylinder pinch roller is in remove in the slide.

In one embodiment, the mobile base further comprises a first guide rail, and the mobile base is slidably connected to the first guide rail and slides along the first guide rail.

In one embodiment, a second guide rail is arranged on the end face of the moving base, and the cylindrical pinch roller is connected with the second guide rail in a sliding mode.

In one embodiment, the device further comprises a connecting block, wherein the cylindrical pressing wheel is arranged on the connecting block and is slidably connected to the second guide rail through the connecting block.

In one embodiment, the device further comprises an elastic part, wherein the elastic part is fixed on the connecting block or the cylindrical pressing wheel, provides pulling force for the connecting block or the cylindrical pressing wheel, and has a tendency of pulling the cylindrical pressing wheel away from the push block.

In one embodiment, the cylindrical puck is at least partially embedded within the connecting block.

In one embodiment, the cylindrical pressing wheel can rotate relative to the connecting block.

In one embodiment, a bundling groove is formed in one end, far away from the moving base, of the cylindrical pressing wheel.

In one embodiment, a groove is formed in one side of the push block close to the guide track plate, an L-shaped structure is formed in one side of the push block close to the guide track plate, and a boss is formed in a protruding part.

Above-mentioned curved line anchor clamps mechanism, through setting up ejector pad and cylinder pinch roller, make ejector pad and cylinder pinch roller set up relatively, and follow the removal of removing the base and remove, and simultaneously, make the guide way set up in grades, the ejector pad is kept away from to the cylinder pinch roller when getting into the second guide way, make the interval between cylinder pinch roller and the ejector pad enlarge, no longer the centre gripping cable, the work piece can comparatively convenient taking out, thereby no longer the line ball when the cylinder pinch roller resets, influence the line ball effect when avoiding reverse line ball.

Drawings

FIG. 1 is a schematic structural diagram of a wire bending fixture mechanism according to an embodiment of the present application;

FIG. 2 is a schematic structural view of a wire bending fixture mechanism according to another embodiment of the present application;

FIG. 3 is a schematic structural view of a wire bending fixture mechanism according to yet another embodiment of the present application;

FIG. 4 is a schematic view of the internal structure of a wire bending fixture mechanism according to yet another embodiment of the present application;

fig. 5 is a schematic structural view of a guide rail plate of a wire bending jig mechanism according to still another embodiment of the present application.

Detailed Description

To facilitate an understanding of the present application, the present application will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present application are given in the accompanying drawings. This application may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used herein in the description of the present application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

The wire bending clamp mechanism provided by the embodiment of the application can take out a cable after the cable is bent, the cable is taken out conveniently, the cable is taken out in the reset process of the push block and the cylindrical pressing wheel, a wire can not be pressed reversely, and the wire pressing effect is good.

The wire bending clamp mechanism according to various embodiments of the present application will be described in detail below with reference to the accompanying drawings.

Referring to fig. 1, which exemplarily shows a schematic structural diagram of a wire bending fixture mechanism 10 according to an embodiment of the present invention, the wire bending fixture mechanism 10 may include a driving member 110, a moving base 120, a cylindrical pressing wheel 130, a pushing block 140 and a guiding track plate 150, the driving member 110 is used for providing a driving force, the moving base 120 is connected to the driving member 110 in a driving manner, the cylindrical pressing wheel 130 is disposed on the moving base 120 and is slidably connected to the moving base 120, the pushing block 140 is fixed on the moving base 120 and is disposed opposite to the cylindrical pressing wheel 130 at a predetermined distance, the cylindrical pressing wheel 130 and the pushing block 140 move along with the movement of the moving base 120, the guiding track plate 150 is provided with a guiding groove 151, the cylindrical pressing wheel 130 is at least partially received in the guiding groove 151 and moves along with the movement of the moving base 120 in the guiding groove 151, when the cylindrical pressing wheel 130 moves in the guiding groove 151, the direction away from the pushing block 140, the guide groove 151 includes a first guide groove 151a and a second guide groove 151b, and the first guide groove 151a and the second guide groove 151b communicate with each other and have different depths to form a stepped structure. The bending of the cable is completed in the process that the cylindrical pressing wheel 130 moves in the first guide groove 151a, and after the cable enters the second guide groove 151b, the distance between the push block 140 and the cylindrical pressing wheel 130 is increased, and the cable is released.

The depth of the first guide groove 151a is smaller than the depth of the second guide groove 151b, in an initial state, the cylindrical pressing wheel 130 is located at one end of the first guide groove 151a, which is far away from the second guide groove 151b, the driving member 110 drives the moving base 120 to move, the pushing block 140 and the cylindrical pressing wheel 130 are driven to move, and the cylindrical pressing wheel 130 moves along the first guide groove 151a and slides to the second guide groove 151 b. When the workpiece is placed on the guide rail plate 150, the part of the workpiece, to which the cable is to be fixed, corresponds to the first guide groove 151a, and the push block 140 and the cylindrical pinch roller 130 are respectively located at both sides of the part of the workpiece, to which the cable is to be fixed, so that the cylindrical pinch roller 130 and the push block 140 respectively slide at both sides of the part of the workpiece, to which the cable is to be fixed, when sliding to the part of the workpiece, the push block 140 and the cylindrical pinch roller 130 respectively bend the cable, thereby fixing the cable on the workpiece and completing the bending of the cable. Cylinder pinch roller 130 and ejector pad 140 continue to remove to second guide way 151b, when cylinder pinch roller 130 enters into in the second guide way 151b, cylinder pinch roller 130 relative movement base 120 removes to the direction of keeping away from ejector pad 140, and laminate and remove in the bottom of second guide way 151b, at this moment, the clearance between ejector pad 140 and the cylinder pinch roller 130 is enlarged, the work piece can be comparatively convenient taking out, thereby no longer the line ball when cylinder pinch roller 130 resets, influence the line ball effect when avoiding reverse line ball.

Referring to fig. 2 and 3, in an embodiment, the wire bending clamping mechanism 10 may further include an outer cover 160, a cavity is disposed in the outer cover 160, the movable base 120 is disposed in the cavity, such that the internal driving structure of the wire bending clamping mechanism 10 is invisible, the cylindrical pressing wheel 130 and the pushing block 140 are at least partially exposed out of the outer cover 160, and the guide track plate 150 is fixed on the outer cover 160. Accordingly, only one side of the fixed guide rail plate 150 is externally visible, thereby achieving internal structural protection, and the housing 160 is provided to facilitate cable placement.

Referring to fig. 1 and 3, in one or more embodiments, the wire bending fixture mechanism 10 may further include a first guide rail 170, the first guide rail 170 is disposed in the cavity, the moving base 120 is slidably connected to the first guide rail 170, and when the driving element 110 operates, the moving base 120 is driven to slide along the first guide rail 170, so as to drive the pushing block 140 and the cylindrical pressing wheel 130 to move along a predetermined track. For example, a sliding groove may be provided on an end surface of the moving base 120 away from the pushing block 140, and the sliding groove is slidably engaged with the first guiding rail 170, so that the moving base 120 is slidably connected with the first guiding rail 170. In the embodiment shown in fig. 1, the movable base 120 is slidably coupled to the first rail 170 via a slider. It is understood that the slider may be a part of the mobile base 120 or may be fixedly connected to the mobile base 120.

Referring to fig. 3, the first rail 170 may be fixed to the outer cover 160. For example, the housing 160 may include a base plate 161, the first rail 170 is fixed on the base plate 161, and the mobile base 120 is fixed on the first rail 170, so that the mobile base 120 can slide smoothly on the first rail 170 under the driving of the driving member 110.

Referring to fig. 2, the outer cover 160 may further include a plurality of side plates 163 and a top plate 165, the side plates 163 are disposed along an edge of the bottom plate 161 and fixedly connected to each other to form a cavity, the top plate 165 and the guide rail plate 150 are fixedly connected to the side plates 163 and cover the cavity, a predetermined gap is reserved between the top plate 165 and the guide rail plate 150 to form a slide way 10a, the slide way 10a is communicated with the guide groove 151, and the push block 140 and the cylindrical pressing wheel 130 move in the slide way 10a under the driving of the moving base 120.

Referring to fig. 1, a second guide rail 180 is disposed on an end surface of the moving base 120, the first guide rail 170 and the second guide rail 180 are respectively located on two opposite sides of the moving base 120, and the cylindrical pressing wheel 130 is slidably connected to the second guide rail 180. With continued reference to fig. 3, in an exemplary embodiment, the wire bending fixture mechanism 10 may further include a connecting block 190, and the cylindrical pressing wheel 130 is disposed on the connecting block 190 and slidably connected to the second guiding rail 180 through the connecting block 190. When the movable slider moves, the movable slider drives the cylindrical pressing wheel 130 to move along the direction of the first guide rail 170 through the second guide rail 180 and the connecting block 190.

In order to realize the paying-off after the cable is pressed, when the cylindrical pressing wheel 130 moves in the guide groove 151, the cylindrical pressing wheel 130 tends to move along the second guide rail 180 in a direction away from the push block 140. For example, in one or more embodiments, the wire clamping mechanism 10 may further include an elastic member (not shown) and connected to the connecting block 190 and the housing 160 through the elastic member, wherein the elastic member provides a pulling force to the connecting block 190, and has a tendency to pull the connecting block 190 away from the push block 140, when the cylindrical roller 130 moves in the first guide groove 151a, the cylindrical roller 130 abuts against the bottom of the first guide groove 151a, the guide track plate 150 prevents the connecting block 190 from moving relative to the moving base 120 through the cylindrical roller 130, when the cylindrical roller 130 enters the second guide groove 151b from the first guide groove 151a, due to the different depths of the first guide groove 151a and the second guide groove 151b, at the moment of exiting from the first guide groove 151a and entering into the second guide groove 151b, the abutting force provided by the guide track plate 150 to the cylindrical roller 130 disappears, the connecting block 190 is pulled by the elastic member, the cable releasing device moves in the direction far away from the push block 140 to drive the cylindrical pressing wheel 130 to move in the direction far away from the push block 140, the gap between the cylindrical pressing wheel 130 and the push block 140 is enlarged, the cable is not clamped any more, and therefore the cable releasing operation is achieved. When the cylindrical pressing wheel 130 moves to the bottom of the second guide groove 151b, the guide rail plate 150 abuts against the cylindrical pressing wheel 130, prevents the cylindrical pressing wheel 130 from moving, and prevents the connecting block 190 from moving. The moving base 120 continues to drive the pushing block 140 and the cylindrical pressing wheel 130 to move along the direction of the first guiding rail 170.

The elastic member may be an extension spring. It is understood that the elastic member can be directly fixed to the cylindrical pressing wheel 130, so as to directly provide the tensile force to the cylindrical pressing wheel 130, rather than indirectly providing the tensile force through the connecting block 190. As long as it can pull the cylindrical pressing wheel 130 to move along the second guiding rail 180. Of course, the movement of the connecting block 190 or the cylindrical pressing wheel 130 can be pulled in other ways, not limited to the way of the elastic member.

In some embodiments, the cylindrical pressing wheel 130 is at least partially embedded in the connecting block 190, so as to prevent the cylindrical pressing wheel 130 from being separated from the connecting block 190, and the connecting block 190 can provide a supporting force to the cylindrical pressing wheel 130 to prevent the cylindrical pressing wheel 130 from being damaged during the movement. For example, with continued reference to FIG. 4, the connecting block 190 may include a sliding portion 191 and a connecting portion 193, the connecting portion 193 fixes the sliding portion 191 of the connecting portion 193, the sliding portion 191 is slidably connected to the second guide rail 180, and the cylindrical pressing wheel 130 is at least partially embedded in the connecting portion 193. For example, the connecting portion 193 may have a recess 193a therein, and the cylindrical puck 130 is inserted into the recess 193a and at least partially exposed from the recess 193 a. Therefore, the connecting portion 193 can move the cylindrical pressing wheel 130 together.

In one or more embodiments, cylindrical pressure wheel 130 can rotate relative to attachment block 190. From this, when cylinder pinch roller 130 is when the line ball, cylinder pinch roller 130 can rotate under the reaction force that the cable provided to cylinder pinch roller 130 realizes buckling to the cable at the rotation in-process, can strengthen the curved line effect. For example, when the cylindrical pressing wheel 130 is accommodated in the concave hole 193a, the cylindrical pressing wheel 130 can rotate after being stressed in the circumferential direction, and of course, a rotating shaft (not shown) may be disposed at the bottom of the concave hole 193a and embedded into the cylindrical pressing wheel 130, so that the cylindrical pressing wheel 130 can rotate with the rotating shaft as an axis.

Referring to fig. 4, a bundling groove 131 may be disposed at an end of the cylindrical pressing wheel 130 away from the moving base 120. For example, the lacing grooves 131 can be disposed around the circumference of the cylindrical puck 130. When the cable is pressed, the copper wire part of the cable is exposed and corresponds to the bundling groove 131. At first, the contact part of the exposed copper wire and the wire bunching groove 131 is regular, the copper wire is not branched, the cylindrical pinch roller 130 moves and rotates while bending the wire in the moving and rotating processes, and the wire bunching groove 131 can play a wire bunching effect on the exposed copper wire and bunch the branched tail end of the copper wire into the wire bunching groove 131; meanwhile, the arrangement of the wire bundling groove 131 can also increase the gap between the pressing block and the cylindrical pressing wheel 130, so that the copper wires are prevented from being excessively flattened and dispersed. Therefore, by providing the wire harness slot 131, the effect of the wire pressing can be greatly improved.

The pushing block 140 is fixed on the movable base 120 and is immovable relative to the movable base 120. For example, the pushing block 140 may be directly fixed on the end surface of the moving base 120 away from the first guide rail 170, and of course, the fixing of the pushing block 140 may also be realized by an additional fixing block or fixing column.

Referring to fig. 4, in one or more embodiments, a groove 140a is disposed at a side of the push block 140 close to the guide rail plate 150, an L-like structure is formed at a side of the push block 140 close to the guide rail plate 150, a protruding portion forms a boss 141, and the boss 141 and the cylindrical pinch roller 130 complete cable bending. After the bending is completed, the arrangement of the groove 140a can also increase the distance between the push block 140 and the cylindrical pressing wheel 130, so as to facilitate the taking out of the cable.

Referring to fig. 5, a fixing portion 153 may be disposed on the guide rail plate, the fixing portion 153 is used for fixing a workpiece, the fixing portion 153 may be disposed near the guide groove 151, when the workpiece is fixed, a portion of the workpiece to be fixed on the cable is suspended on the first guide groove 151a and disposed opposite to the first guide groove 151a, and the push block 140 and the cylindrical pressing wheel 130 are respectively located at two sides of the portion of the workpiece to be fixed on the cable.

The first guide groove 151a and the second guide groove 151b may be connected by a smooth curved surface to facilitate movement of the cylindrical puck 130 and, at the same time, facilitate repositioning of the cylindrical puck 130.

When the cable is bent by using the wire bending clamping mechanism 10, the cylindrical pressing wheel 130 is retracted to an end of the first guide groove 151a away from the second guide groove 151b, then the workpiece is placed on the fixing position 153 for fixing, and the cable is passed through the through hole on the workpiece, at this time, the cable can be horizontally placed on the top plate 165 of the outer cover 160. Make driving piece 110 begin work, under driving piece 110's the driving, movable base 120 removes along first guide rail 170, drive ejector pad 140 and cylinder pinch roller 130 and remove to the direction that is close to the cable, remove certain distance after, the boss 141 of ejector pad 140 and cylinder pinch roller 130 contact with the cable respectively in the both sides of work piece, ejector pad 140 and cylinder pinch roller 130 continue to remove, the cable that promotes the work piece both sides removes, make the cable buckle, when bending the cable, the copper line part of cable enters into in the bunch groove 131 of cylinder pinch roller 130, and realize bunching along with cylinder pinch roller 130's rotation, cylinder pinch roller 130 realizes the buckling of cable in removal and rotation process. Along with the continuation antedisplacement of cylinder pinch roller 130, cylinder pinch roller 130 enters into second guide way 151b, and under the effect of pulling force, cylinder pinch roller 130 moves along second guide rail 180, keeps away from ejector pad 140, and simultaneously, the recess 140a part of ejector pad 140 corresponds with the department of buckling of cable, and the cable no longer is by ejector pad 140 and cylinder pinch roller 130 centre gripping, can pick up the cable, breaks away from the fixed position 153 with the work piece simultaneously and fixes, and the cable of accomplishing a work piece is buckled fixedly.

Above-mentioned curved line anchor clamps mechanism 10, through setting up ejector pad 140 and cylinder pinch roller 130, make ejector pad 140 and cylinder pinch roller 130 set up relatively, and move along the removal of removing base 120, and simultaneously, make guide way 151 set up in grades, cylinder pinch roller 130 is when getting into second guide way 151b, ejector pad 140 is kept away from to cylinder pinch roller 130, make the interval between cylinder pinch roller 130 and the ejector pad 140 enlarge, no longer the centre gripping cable, the work piece can comparatively convenient taking out, thereby no longer the line ball when cylinder pinch roller 130 resets, influence the line ball effect when avoiding reverse line ball.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the utility model. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. A wire bending clamp mechanism is characterized by comprising a driving piece, a movable base, a cylindrical pressing wheel, a pushing block and a guide track plate, wherein,

the movable base is in transmission connection with the driving piece;

the cylindrical pinch roller is arranged on the movable base and is connected to the movable base in a sliding manner;

the push block is fixed on the movable base, is arranged opposite to the cylindrical pinch roller and is spaced by a preset distance, and the cylindrical pinch roller and the push block move along with the movement of the movable base;

be provided with the guide way on the direction track board, the cylinder pinch roller is partial at least accept in the guide way, and follow the removal of moving the base is in the guide way removes, the cylinder pinch roller is in when the guide way removes, have to keeping away from the trend that the direction of ejector pad removed, the guide way includes first guide way and second guide way, first guide way with the second guide way communicates each other, and has different degree of depth in order to form the echelonment structure.

2. The wire bending clamp mechanism according to claim 1, further comprising a housing having a cavity disposed therein, said moveable base being disposed within said cavity;

the dustcoat includes bottom plate, a plurality of curb plates and roof, a plurality of curb plates along the edge of bottom plate sets up to each other fixed connection surrounds and forms the cavity, the roof reaches direction track board fixed connection in the curb plate, and the lid fits the cavity the roof with reserve between the direction track board and have predetermined clearance, form the slide, the slide with the guide way intercommunication under the drive of moving the base, the ejector pad reaches the cylinder pinch roller is in remove in the slide.

3. The wire bending fixture mechanism according to claim 1, further comprising a first rail, said moving base being slidably coupled to said first rail and slidable along said first rail.

4. The wire bending clamp mechanism according to claim 1 or 3, wherein a second guide rail is arranged on the end surface of the movable base, and the cylindrical pinch roller is slidably connected to the second guide rail.

5. The wire bending clamp mechanism according to claim 4, further comprising a connecting block, wherein the cylindrical pressing wheel is disposed on the connecting block and slidably connected to the second guide rail through the connecting block.

6. The wire bending clamp mechanism according to claim 5, further comprising an elastic member fixed to the connecting block or the cylindrical pinch roller to provide a pulling force to the connecting block or the cylindrical pinch roller with a tendency to pull the cylindrical pinch roller away from the push block.

7. The wire clamp mechanism of claim 5 wherein said cylindrical pinch roller is at least partially embedded within said connecting block.

8. The wire clamp mechanism of claim 5 wherein said cylindrical pinch roller is rotatable relative to said connector block.

9. The wire bending clamp mechanism according to claim 1 or 8, wherein one end of the cylindrical pinch roller away from the moving base is provided with a wire bundling groove.

10. The wire bending clamp mechanism according to claim 1, wherein a groove is formed on one side of the push block close to the guide track plate, an L-like structure is formed on one side of the push block close to the guide track plate, and a boss is formed on a protruding part.

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