JP2016030625A - Reinforcement binding machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a reinforcement binding machine which does not generate repeated input on brake means even when adjustment of a gear ratio or the like is not performed.SOLUTION: A reinforcement binding machine 10 for binding a reinforcement by feeding a binding wire W and winding the wire on circumference of the reinforcement includes: a wire reel 13 freely rotatably supported by a binding machine main body 11; brake means 36 for stopping rotation of the wire reel 13; a power source 21 for actuating the brake means 36; and a transmission member 31 which transmits a power of the power source 21 to the brake means 36. Therein, a buffer mechanism is provided on a power transmission course for transmitting the power of the brake means 36 or the power source 21 to the brake means 36.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a reinforcing bar binding machine that binds a plurality of reinforcing bars by winding and twisting a wire around the reinforcing bars.

  Conventionally, in this type of reinforcing bar binding machine, a wire is fed from a wire reel by feeding means, and the fed wire is curled so as to surround the reinforcing bar in a curl forming portion. When the wire feed of a predetermined length is performed, the wire feed stops, and the wires are twisted and bound so that the reinforcing bars are tightened by the twisting means. At this time, since the wire reel continues to rotate due to inertia even after the wire feed is stopped, a brake means for applying braking to the rotation of the wire reel is provided to stop the rotation of the wire reel.

  For example, in Patent Document 1, a brake means that can be engaged with a peripheral portion of a wire reel and a brake lever that operates the brake means are provided, and the brake lever is interlocked with a torsion motor that drives a torsion hook. When the torsion motor rotates forward, the brake means is operated by the brake lever to brake the rotation of the wire reel, and when the torsion motor rotates backward, the brake lever and the brake means are operated in the reverse direction. A wire reel brake mechanism for releasing the brake is disclosed. Thus, if the brake means is operated in conjunction with the torsion motor, the rotation of the wire reel can be braked almost simultaneously with the end of the predetermined wire feed.

Japanese Patent No. 3531150

  However, in the structure described in Patent Document 1 described above, the brake lever is rotated in accordance with the rotation of the torsion motor that has an overwhelming amount of rotation compared to the amount of rotation of the brake lever. Although a mechanism for absorbing is provided, in this case, the rotating brake lever may repeatedly engage and disengage with respect to the brake means (see FIGS. 9 and 11 in Patent Document 1). . When the brake lever is repeatedly engaged and disengaged, the number of times that the impact is applied to the component increases, and there is a problem that the durability of the component is affected. There is also a problem that noise is increased by repeating engagement and disengagement.

  Note that the rotation angle of the brake lever is limited by adjusting the gear ratio on the transmission path for transmitting the rotation of the torsion motor to the brake lever so that the brake lever does not repeat engagement and disengagement. It is also possible to adjust (see FIG. 7 etc. of Patent Document 1). However, the size and arrangement of the gears are limited because there is a limit to the size of the machine body and all the parts must be housed in the housing in order to prevent dust from adhering to the power transmission unit. For this reason, the limited space may not be effectively used. In addition, in general, the number of rotations during forward rotation for a twisting motor is greater than the number of rotations during reverse rotation for returning from the torsion operation to the standby position. When the rotation angle of the lever is adjusted, the difference in the rotational speed between the forward rotation and the reverse rotation cannot be absorbed, so some change is necessary on the torsion mechanism side.

  Accordingly, it is an object of the present invention to provide a reinforcing bar binding machine that can reliably operate and release a brake without adjusting a gear ratio and the like and that does not generate repeated input to the brake means. .

  The present invention has been made to solve the above-described problems, and is characterized by the following.

  The invention described in claim 1 is a reinforcing bar binding machine that feeds a binding wire and wraps it around a reinforcing bar to bind it, a wire reel that is rotatably supported by the binding machine body, and stops the rotation of the wire reel Brake means for causing the brake means to operate, a power source for operating the brake means, and a transmission member for transmitting the power of the power source to the brake means, the brake means or the power of the power source being supplied to the brake A buffer mechanism is provided on the power transmission path for transmitting to the means.

  According to a second aspect of the present invention, in addition to the feature of the first aspect of the present invention, the power source moves the transmission member in the forward direction when operating the brake means in the stop direction of the wire reel. In addition, the transmission member is driven in the backward direction when the brake means is operated in the direction of releasing the stop of the wire reel.

  The invention described in claim 3 is characterized in that, in addition to the feature of the invention described in claim 1 or 2, the rotation of the wire reel is suppressed by engagement with the brake means.

  According to a fourth aspect of the invention, in addition to the feature of the third aspect of the invention described above, the buffer mechanism is an engagement bias that biases the brake means in a direction to engage with the wire reel. And the transmission member moves the brake means in a direction in which the engagement with the wire reel is released against the urging force of the engagement urging means. .

  According to a fifth aspect of the present invention, in addition to the features of the third or fourth aspect of the invention described above, the buffer mechanism attaches the brake means in a direction in which the engagement with the wire reel is released. The transmission member is configured to move in a direction to engage the wire reel against a biasing force of the release biasing means. .

  The invention according to claim 6 is characterized in that, in addition to the features of the invention according to any one of claims 1 to 5, the buffer mechanism is configured by making the brake means elastically deformable. To do.

  The invention according to claim 7 drives a twisting hook for twisting and binding the binding wire as the power source in addition to the features of the invention according to any one of the first to sixth aspects. The transmission member is advanced or retracted in conjunction with the advancement or retraction of the torsion hook.

  The invention according to claim 1 is as described above, and the buffer mechanism is provided on the power transmission path for transmitting the power of the brake means or the power source to the brake means. Even when the brake means is locked, it is possible to prevent excessive input from being generated by the transmission member, or to absorb excessive input by the buffer mechanism even when excessive input from the transmission member is generated.

  The invention according to claim 2 is as described above, and the power source drives the transmission member in the forward direction when the brake means is operated in the stop direction of the wire reel, and the brake means is When the wire reel is operated in the stop release direction, the transmission member is driven in the backward direction, so that the transmission member does not repeatedly input to the brake means in both cases of engagement and disengagement. Therefore, the problem that the durability of the component is reduced and the noise is increased due to repeated impact on the component does not occur. Further, since it is not necessary to consider the size and arrangement of the gears, the brake mechanism can be arranged by effectively utilizing the limited space.

  By the way, when the transmission member is moved forward or backward, even if the brake means is locked due to foreign matter mixed in or a displacement of the engaging portion, the transmission member tries to operate the brake means as it is. There is a possibility that an excessive load is applied to the members constituting the path for transmitting power from the brake to the brake means. However, according to the present invention, since a buffer mechanism for absorbing the load is provided so that an excessive load is not applied to the members constituting the brake means and the transmission path, the excessive input by the transmission member is not generated or the transmission is transmitted. Even when an excessive input is generated by the member, the buffer mechanism can absorb the excessive input.

  The invention according to claim 3 is as described above. Since the rotation of the wire reel is suppressed by the engagement with the brake means, the rotation of the wire reel can be stopped with a simple structure. .

  The invention according to claim 4 is as described above, and the buffer mechanism is configured to include an engagement urging unit that urges the brake unit in a direction to engage the wire reel, The transmission member moves the brake means in a direction in which the engagement with the wire reel is released against the urging force of the engagement urging means. According to such a structure, when the brake means engages with the wire reel, the brake means elastically acts on the wire reel using the biasing force of the engagement biasing means. Therefore, even when the brake means is pressed against the protruding part without entering the engaging part of the wire reel, it is possible to avoid the brake means and the wire reel from being locked due to elastic deformation of the engaging biasing means.

  The invention according to claim 5 is as described above, and the buffer mechanism includes a release urging unit that urges the brake unit in a direction in which the engagement with the wire reel is released. The transmission member moves the brake means in a direction to engage the wire reel against the urging force of the release urging means. According to such a structure, when the engagement between the brake means and the wire reel is released, the brake means moves away from the wire reel using the urging force of the release urging means. Therefore, even when a foreign object or the like entering the machine interferes with the brake means and the brake means cannot move in the direction away from the wire reel, it is avoided that the release biasing means is elastically deformed and the brake means is locked. it can.

  The invention according to claim 6 is as described above, and the buffer mechanism is configured by making the brake means elastically deformable. According to such a structure, the brake means can be prevented from being locked by elastically deforming the brake means itself.

  Further, the invention according to claim 7 is as described above, and a torsion motor for driving a torsion hook for twisting and binding the binding wire is used as the power source. The brake means can be operated without using a power source.

  In addition, the transmission member moves forward or backward in conjunction with the forward or backward movement of the torsion hook, and does not directly act on the brake mechanism with the rotational force of the torsion motor. Therefore, there is no need to be aware of the difference between the rotational speed for forward rotation and the rotational speed for reverse rotation for returning from the twisting operation to the standby position. That is, the torsion motor can be used for the brake mechanism only by retrofitting the brake mechanism to the conventional torsion mechanism without any particular change on the torsion mechanism side.

It is the schematic which shows the internal structure of a reinforcing bar binding machine, and is the figure which looked at the reinforcing bar binding machine from the right. It is the schematic which shows the internal structure of a reinforcing bar binding machine, and is the figure which looked at the reinforcing bar binding machine from the left. It is the schematic which shows the internal structure of a reinforcing bar binding machine, Comprising: It is the figure which looked at the reinforcing bar binding machine from the top. It is an external view of the twist mechanism and brake mechanism which concern on 1st Embodiment. It is an action | operation figure of the brake mechanism which concerns on 1st Embodiment, Comprising: (a) The figure of an engagement release state, (b) The figure of an engagement state. It is an external view of the twist mechanism and brake mechanism which concern on 2nd Embodiment. It is an action | operation figure of the brake mechanism which concerns on 2nd Embodiment, Comprising: (a) The figure of an engagement release state, (b) The figure of an engagement state. It is an external view of the twist mechanism and brake mechanism which concern on 3rd Embodiment. It is an external view of the twist mechanism and brake mechanism which concern on 4th Embodiment. It is an external view of the twist mechanism and brake mechanism which concern on 5th Embodiment. It is an action | operation figure of the brake mechanism which concerns on 5th Embodiment, Comprising: (a) The figure of an engagement release state, (b) The figure of an engagement state. It is an external view of the twist mechanism and brake mechanism which concern on 6th Embodiment. It is an operation | movement figure of the brake mechanism which concerns on 6th Embodiment, Comprising: (a) The figure of an engagement release state, (b) The figure of an engagement state. It is an external view of the twist mechanism and brake mechanism which concern on 7th Embodiment. It is an action | operation figure of the brake mechanism which concerns on 7th Embodiment, Comprising: (a) The figure of an engagement release state, (b) The figure of an engagement state. It is an external view of the twist mechanism and brake mechanism which concern on 8th Embodiment. It is an external view of the twist mechanism and brake mechanism which concern on 9th Embodiment. It is an external view of the twist mechanism and brake mechanism which concern on 10th Embodiment. It is an external view of the twist mechanism and brake mechanism which concern on 11th Embodiment. It is an external view of the twist mechanism and brake mechanism which concern on 12th Embodiment. It is an external view of the twist mechanism and brake mechanism which concern on 13th Embodiment. It is an external view of the twist mechanism and brake mechanism which concern on 14th Embodiment. It is an external view of the twist mechanism and brake mechanism which concern on 15th Embodiment. It is an external view of the twist mechanism and brake mechanism which concern on 16th Embodiment. It is an external view of the twist mechanism and brake mechanism which concern on 17th-20th embodiment. It is an action | operation figure of the brake mechanism which concerns on 17th-20th embodiment, Comprising: (a) The figure of an engagement release state, (b) The figure of an engagement state. It is an operation | movement figure of the brake mechanism which concerns on 17th Embodiment, Comprising: (a) The figure of an engagement state, (b) The figure of the state which contacted the protrusion part of the wire reel. It is an action | operation figure of the brake mechanism which concerns on 17th Embodiment, Comprising: (a) The figure of an engagement releasing state, (b) The figure of the state which interfered with the foreign material. It is an action | operation figure of the brake mechanism which concerns on 18th Embodiment, Comprising: (a) The figure of an engagement state, (b) The figure of the state which contacted the protrusion part of the wire reel. It is an action | operation figure of the brake mechanism which concerns on 18th Embodiment, Comprising: (a) The figure of an engagement cancellation | release state, (b) The figure of the state which interfered with the foreign material. It is an action | operation figure of the brake mechanism which concerns on 19th Embodiment, Comprising: (a) The figure of an engagement state, (b) The figure of the state which contacted the protrusion part of the wire reel. It is an action | operation figure of the brake mechanism which concerns on 19th Embodiment, Comprising: (a) The figure of an engagement releasing state, (b) The figure of the state which interfered with the foreign material. It is the schematic of the brake mechanism which concerns on 20th Embodiment. It is an external view of the twist mechanism and brake mechanism which concern on the modification of 17th-20th embodiment. (A) Front view of clutch mechanism, (b) AA line sectional view of clutch mechanism. It is an external view of the twist mechanism and brake mechanism which concern on Example 1 of a friction brake. It is an action | operation figure of the brake mechanism which concerns on Example 1 of a friction brake, Comprising: (a) The figure of an engagement release state, (b) The figure of an engagement state. It is an external view of the twist mechanism and brake mechanism which concern on Example 1 of a friction brake. It is an action | operation figure of the brake mechanism which concerns on the example 2 of a friction brake, Comprising: (a) The figure of an engagement release state, (b) The figure of an engagement state. It is an action | operation figure of the brake mechanism which concerns on Example 3 of a friction brake, Comprising: (a) The figure of an engagement release state, (b) The figure of an engagement state. It is a figure explaining the disengagement state of the brake mechanism which concerns on Example 4 of a friction brake, Comprising: (a) Side view of brake mechanism, (b) Partially enlarged bottom view of brake mechanism, (c) A of brake mechanism It is -A sectional drawing. It is a figure explaining the engagement state of the brake mechanism which concerns on Example 4 of a friction brake, Comprising: (a) The side view of a brake mechanism, (b) It is AA sectional drawing of a brake mechanism. It is a figure explaining the action | operation of the rotating plate of the brake mechanism which concerns on Example 4 of a friction brake, Comprising: (a) Side view of rotating plate, (b) Enlarged view near rotating plate in disengaged state, (c) It is an enlarged view near the rotating plate in the combined state.

(First embodiment)
A first embodiment of the present invention will be described.

  As shown in FIGS. 1 to 3, the reinforcing bar binding machine 10 according to the present embodiment feeds a wire W from a wire reel 13 rotatably arranged on the binding machine body 11 to a predetermined length, and a plurality of wires W are rebars. After the wire is wound around, a plurality of bundles of the wires W are twisted and bound.

  The wire reel 13 is rotatably supported by the binding machine body 11 and is configured to be detachable from the binding machine body 11 only by operating a lever (not shown). A wire W for binding is wound around the wire reel 13, and after the wire reel 13 is mounted on the binding machine main body 11, the wire W wound around the wire reel 13 is pulled out and set.

  The wire reel 13 is provided with a flange 13a on a side portion, and a plurality of engaging portions 13b and protruding portions 13c are alternately formed in a substantially sawtooth shape on the flange 13a. The engaging portion 13b faces a brake means 36 described later, and the rotation of the wire reel 13 is stopped when the brake means 36 is engaged with the engaging portion 13b.

  The wire W drawn and set from the wire reel 13 is sent out in the direction of the curl forming portion 12 by a feed motor (not shown). The curl forming unit 12 guides the wire W fed to the tip of the machine to be bent in a loop shape, and the wire W fed to the curl forming unit 12 is guided along the curl forming unit 12. As a result, the plurality of wires W are curled so as to surround the periphery of the reinforcing bar multiple times.

  The binding machine body 11 is provided with a twisting mechanism 20 for twisting and binding the wires W. As shown in FIG. 4, the torsion mechanism 20 according to the present embodiment includes a torsion motor 21, a gear 22, a screw shaft part 23, an advancing / retracting cylinder part 24, and a torsion hook 25.

The torsion motor 21 is for driving the torsion hook 25, and is controlled to start rotating in accordance with a predetermined timing from the stage before the wire W feeding operation is completed. In the present embodiment, the torsion motor 21 is also used as a power source for operating a brake means 36 described later.
The gear 22 is a gear for transmitting the rotational force of the torsion motor 21 to the screw shaft portion 23.

  The screw shaft portion 23 is a shaft member that is rotated by the rotational force of the torsion motor 21 transmitted through the gear 22. The screw shaft portion 23 is supported so as to be rotatable with respect to the binding machine body 11. The outer peripheral surface of the screw shaft portion 23 is threaded, and is screwed into an inner peripheral surface of an advance / retreat cylinder portion 24 described later.

  The advancing / retreating cylinder part 24 is a cylindrical member having a screw shaft part 23 inserted therein. The advancing / retracting cylinder portion 24 is supported so as to be movable back and forth with respect to the binding machine body 11 and is supported so as not to rotate. The inner peripheral surface of the advance / retreat cylinder portion 24 is threaded and is screwed with the outer peripheral surface of the screw shaft portion 23. As described above, when the inner peripheral surface of the advance / retreat cylinder portion 24 and the outer periphery surface of the screw shaft portion 23 are screwed together, the advance / retreat cylinder portion 24 moves back and forth when the torsion motor 21 rotates. Yes.

  The torsion hook 25 is a pair of claw-like members attached to the tip of the advance / retreat cylinder portion 24. The twisting hook 25 is configured to open and close in accordance with the advance / retreat operation of the advance / retreat cylinder portion 24 by a known structure.

  The torsion mechanism 20 described above operates as follows. First, when the trigger of the reinforcing bar binding machine 10 is operated, the wire W is fed out by a predetermined amount and wound by the curl forming unit 12 in a loop shape. Thereafter, the torsion motor 21 rotates forward and the rotation is transmitted to the screw shaft portion 23 via the gear 22. Although the screw shaft portion 23 rotates, the advance / retreat cylinder portion 24 cannot rotate, and therefore the advance / retreat cylinder portion 24 is sent forward by the action of the screwed screw. Thus, the torsion hook 25 moves forward to a position where it comes into contact with the wire W by the forward / backward moving cylinder portion 24 being sent forward. At this time, the torsion hook 25 operates in the closing direction in conjunction with the advancement of the advancing / retreating cylinder portion 24, so that the torsion hook 25 grips a part of the wire loop. The advancing / retracting cylinder portion 24 is unsupported in the rotational direction at the advanced position, and rotates together with the screw shaft portion 23. At this time, the twisting hook 25 holding the wire W is also rotated to twist the wire. Note that a cutter (not shown) is activated to cut the wire W while the advancing / retreating cylinder portion 24 moves forward.

When the twisting operation is completed as described above, the torsion motor 21 rotates in the reverse direction and the screw shaft portion 23 rotates in the reverse direction. As a result, the forward / backward moving cylinder portion 24 and the twisting hook 25 also move rearward. At this time, the twisting hook 25 is opened and the wire W is released. The torsion motor 21 reverses until the advance / retreat cylinder portion 24 and the torsion hook 25 move to the standby position. When the advancing / retracting cylinder portion 24 and the torsion hook 25 move to the standby position, the torsion motor 21 stops and a series of operations is completed.
Next, the brake mechanism 30 according to the present embodiment will be described.

  As shown in FIG. 4, the brake mechanism 30 according to the present embodiment includes an advance / retreat fixing portion 31, a linear motion member 32, a swing member 34, a brake means 36, and an engagement biasing means 37. ing.

  The advance / retreat fixing portion 31 is a transmission member for transmitting the power of the torsion motor 21 as a power source to the brake means 36. The advance / retreat fixing portion 31 is fixed to the advance / retreat cylinder portion 24 of the torsion mechanism 20, and moves forward or backward in conjunction with the advance / retreat operation of the advance / retreat cylinder portion 24. In other words, the advance / retreat fixing portion 31 moves forward integrally with the advance / retreat cylinder portion 24 when the torsion motor 21 rotates forward, and rearward integrally with the advance / retreat cylinder portion 24 when the torsion motor 21 reverses. To move to. The advancing / retreating fixing portion 31 is formed with an engaging portion 31a for engaging with a linear motion member 32 described later.

  The linear motion member 32 is a member that is supported so as to be movable substantially parallel to the advance / retreat direction of the advance / retreat fixing portion 31. A receiving portion 32a engageable with the engaging portion 31a of the advance / retreat fixing portion 31 is formed at one end portion in the longitudinal direction of the linear motion member 32, and the other end portion is connected to the swing member 34 by a connection pin 32c. Has been. The linear motion member 32 is slidably guided by a guide pin 33 fixed to the binding machine body 11. Specifically, the linear motion member 32 includes a guide groove 32b in the longitudinal direction, and the linear motion member 32 slides back and forth along the guide groove 32b by engaging the guide pin 33 with the guide groove 32b. It is possible.

  The linear motion member 32 according to the present embodiment is configured to move when the receiving portion 32a is pushed by the engaging portion 31a when the advance / retreat fixing portion 31 moves. In this embodiment, as shown in FIGS. 4 and 5, since the receiving portion 32a is provided behind the engaging portion 31a, the torsion motor 21 reverses and the advance / retreat fixing portion 31 moves rearward. When moved, the receiving portion 32a is pushed by the engaging portion 31a. However, when the torsion motor 21 rotates forward and the advance / retreat fixing portion 31 moves forward, the receiving portion 32a is not pushed by the engaging portion 31a. It has become.

  The swing member 34 is a member provided so as to be swingable with respect to the binding machine main body 11 with the rotation shaft 35 as an axis, and an end thereof is connected to the linear motion member 32 via a connection pin 32c. Therefore, when the linear motion member 32 moves forward, the swinging member 34 swings forward in conjunction with this, and when the linear motion member 32 moves rearward, the swinging member 34 interlocks with this. Also swings backward. Since the swing member 34 is fixed to the rotary shaft 35, the rotary shaft 35 is also rotated integrally when the swing member 34 swings.

  The brake means 36 is a member that swings about the rotation shaft 35, and has a claw portion 36a at the tip. The claw portion 36 a is disposed so as to face the peripheral portion of the wire reel 13, and can be engaged with the engaging portion 13 b of the wire reel 13 when the brake means 36 swings in the direction of the wire reel 13. Yes. The brake means 36 rotates integrally with the rotating shaft 35. Therefore, as shown in FIG. 5, when the swing member 34 swings forward, the claw portion 36 a is engaged with the engagement portion 13 b of the wire reel 13 in conjunction with this (the stop direction of the wire reel 13). ). Further, when the swinging member 34 swings backward, the swinging member 34 swings in the direction in which the engagement with the engaging portion 13b of the wire reel 13 is released (the stop releasing direction of the wire reel 13).

The engagement urging means 37 is a torsion coil spring that urges the brake means 36 in a direction to engage the wire reel 13. One end of the engagement biasing means 37 is supported by a spring receiving portion 39 that is a part of the binding machine body 11, and the other end is engaged with the brake means 36 to bias the brake means 36.
The brake mechanism 30 described above operates as follows (see FIG. 5).

  First, the trigger of the reinforcing bar binding machine 10 is operated to perform a twisting operation. At this time, the torsion motor 21 rotates in the forward rotation direction. With this rotation, the advance / retreat fixing portion 31 moves in the forward direction together with the advance / retreat cylinder portion 24. Due to this movement, the force that pushed the receiving portion 32a of the linear motion member 32 by the engaging portion 31a of the advance / retreat fixing portion 31 disappears, so that the brake means 36 is engaged with the wire reel 13 by the urging force of the engaging urging means 37. Swings in the mating direction. As described above, the torsion motor 21 as the power source drives the forward / backward fixing portion 31 as the transmission member in the forward direction to engage the brake means 36 with the wire reel 13. When the brake means 36 is engaged with the wire reel 13, the rotation of the wire reel 13 that has been rotated by inertia can be stopped.

  In addition, when the brake means 36 swings, the claw portion 36a of the brake means 36 may not enter the engagement portion 13b of the wire reel 13 and the claw portion 36a may contact the protruding portion 13c of the wire reel 13. is there. If the claw portion 36a is forcibly pressed against the wire reel 13 in such a state, the brake means 36 and the wire reel 13 may be locked, resulting in a malfunction. However, according to the present embodiment, the brake means 36 swings in the direction in which the brake means 36 is engaged with the wire reel 13 by the urging force of the engagement urging means 37, so that the engagement urging means is applied when a certain load is applied. 37 can be elastically deformed to release the force. As described above, since the buffer mechanism is provided for elastically buffering so that an excessive load is not applied to the brake means 36, excessive input by the transmission member is prevented from occurring or even when excessive input by the transmission member is generated. A buffer mechanism can absorb excess input.

  When the wire reel 13 is stopped by the operation as described above and the twisting operation is finished, the torsion motor 21 is reversely rotated, and the advance / retreat fixing portion 31 moves in the backward direction together with the advance / retreat cylinder portion 24 by this rotation. By this movement, the engaging portion 31a of the advance / retreat fixing portion 31 pushes the receiving portion 32a of the linear motion member 32, so that the engagement with the wire reel 13 is released against the urging force of the engaging urging means 37. The brake means 36 swings in the direction. Thus, the torsion motor 21 as the power source drives the forward / backward fixing portion 31 as the transmission member in the backward direction to release the brake means 36 from the wire reel 13. Then, the torsion motor 21 rotates until the standby state as shown in FIG.

(Second Embodiment)
A second embodiment of the present invention will be described. As shown in FIGS. 6 and 7, the feature point of the present embodiment is that the receiving portion 32a of the linear motion member 32 is disposed at a position different from that of the first embodiment, and the engagement of the first embodiment is performed. Instead of the biasing means 37, a release biasing means 38 is provided. Note that the basic configuration of the present embodiment is not different from that of the first embodiment, and therefore, only the portions that are different from the first embodiment will be described while avoiding redundant description.

  As shown in FIGS. 6 and 7, in the linear motion member 32 according to the present embodiment, the receiving portion 32a is provided in front of the engaging portion 31a. When the portion 31 moves forward, the receiving portion 32a is pushed by the engaging portion 31a, but when the torsion motor 21 reverses and the advance / retreat fixing portion 31 moves backward, the receiving portion 32a is engaged with the engaging portion. It is not pushed by 31a.

The release biasing means 38 is a torsion coil spring that biases the brake means 36 in a direction in which the engagement with the wire reel 13 is released. One end of the release biasing means 38 is supported by a spring receiving portion 39 which is a part of the binding machine body 11, and the other end is engaged with the brake means 36 to bias the brake means 36.
The brake mechanism 30 described above operates as follows (see FIG. 7).

  First, the trigger of the reinforcing bar binding machine 10 is operated to perform a twisting operation. At this time, the torsion motor 21 rotates in the forward rotation direction. With this rotation, the advance / retreat fixing portion 31 moves in the forward direction together with the advance / retreat cylinder portion 24. By this movement, the engaging portion 31a of the advance / retreat fixing portion 31 pulls up the receiving portion 32a of the linear motion member 32, and the brake means 36 in a direction to engage the wire reel 13 against the urging force of the release urging means 38. Swings. As described above, the torsion motor 21 as the power source drives the forward / backward fixing portion 31 as the transmission member in the forward direction to engage the brake means 36 with the wire reel 13. When the brake means 36 is engaged with the wire reel 13, the rotation of the wire reel 13 that has been rotated by inertia can be stopped.

  When the wire reel 13 is stopped by the operation as described above and the twisting operation is finished, the torsion motor 21 is reversely rotated, and the advance / retreat fixing portion 31 moves in the backward direction together with the advance / retreat cylinder portion 24 by this rotation. This movement eliminates the force that the engaging portion 31a of the advance / retreat fixing portion 31 has lifted the receiving portion 32a of the linear motion member 32, so that the brake means 36 is engaged with the wire reel 13 by the urging force of the release urging means 38. It swings in the direction to cancel. Then, the torsion motor 21 rotates until the standby state as shown in FIG.

  When the brake means 36 swings in the direction in which the engagement with the wire reel 13 is released, the brake means 36 interferes with a foreign matter or the like that has entered the inside of the machine, and the brake means 36 is prevented from swinging. There is a case. If the brake means 36 is forcibly swung in such a state, the brake means 36 may be locked, resulting in malfunction. However, according to the present embodiment, the brake means 36 is swung in the direction in which the engagement with the wire reel 13 is released by the urging force of the release urging means 38, so that it is released when a certain load is applied. The biasing means 38 can be elastically deformed to release the force. As described above, since the buffer mechanism is provided for elastically buffering so that an excessive load is not applied to the brake means 36, excessive input by the transmission member is prevented from occurring or even when excessive input by the transmission member is generated. A buffer mechanism can absorb excess input.

(Third embodiment)
A third embodiment of the present invention will be described. As shown in FIG. 8, the feature of this embodiment is that a first link member 40 and a second link member 41 are provided instead of the linear motion member 32 of the first embodiment. Note that the basic configuration of the present embodiment is not different from that of the first embodiment, and therefore, only the portions that are different from the first embodiment will be described while avoiding redundant description.

  The 1st link member 40 is a member attached so that rotation was possible centering on the rotation fulcrum 40b. The first link member 40 includes a receiving portion 40 a that can be engaged with the engaging portion 31 a of the advance / retreat fixing portion 31, and a joint portion 40 c that is rotatably connected to the second link member 41.

  The first link member 40 according to the present embodiment is moved when the receiving portion 40a is pushed by the engaging portion 31a when the advance / retreat fixing portion 31 moves. In this embodiment, as shown in FIG. 8, since the receiving portion 40a is provided behind the engaging portion 31a, the torsion motor 21 reverses and the advance / retreat fixing portion 31 moves rearward. The receiving portion 40a is pushed by the engaging portion 31a. However, when the torsion motor 21 rotates forward and the advance / retreat fixing portion 31 moves forward, the receiving portion 40a is not pushed by the engaging portion 31a. Yes.

  The second link member 41 is a member rotatably connected to the first link member 40 at the joint portion 40c, and is configured to move back and forth in conjunction with the turning operation of the first link member 40. Yes. The second link member 41 has an end on the opposite side of the joint portion 40c connected to the swing member 34 by a connection pin 41a. When the second link member 41 moves forward, the second link member 41 swings in conjunction therewith. The member 34 also swings forward, and when the second link member 41 moves rearward, the swing member 34 swings backward in conjunction with this movement.

  Thus, even when the link mechanism is configured by the first link member 40 and the second link member 41 instead of the linear motion member 32 of the first embodiment, the same effect as that of the first embodiment can be obtained. Can do.

(Fourth embodiment)
A fourth embodiment of the present invention will be described. As shown in FIG. 9, the characteristic point of this embodiment is that a first link member 40 and a second link member 41 are provided instead of the linear motion member 32 of the second embodiment. Since the basic configuration of the present embodiment is not different from that of the second embodiment, only the differences from the second embodiment will be described while avoiding redundant description.

  The 1st link member 40 is a member attached so that rotation was possible centering on the rotation fulcrum 40b. The first link member 40 includes a receiving portion 40 a that can be engaged with the engaging portion 31 a of the advance / retreat fixing portion 31, and a joint portion 40 c that is rotatably connected to the second link member 41.

  The first link member 40 according to the present embodiment is moved when the receiving portion 40a is pushed by the engaging portion 31a when the advance / retreat fixing portion 31 moves. In this embodiment, as shown in FIG. 9, since the receiving portion 40a is provided in front of the engaging portion 31a, the torsion motor 21 rotates forward and the advance / retreat fixing portion 31 moves forward. Sometimes, the receiving portion 40a is pushed by the engaging portion 31a. However, when the torsion motor 21 reverses and the advance / retreat fixing portion 31 moves backward, the receiving portion 40a is not pushed by the engaging portion 31a. Yes.

  The second link member 41 is a member rotatably connected to the first link member 40 at the joint portion 40c, and is configured to move back and forth in conjunction with the turning operation of the first link member 40. Yes. The second link member 41 has an end on the opposite side of the joint portion 40c connected to the swing member 34 by a connection pin 41a. When the second link member 41 moves forward, the second link member 41 swings in conjunction therewith. The member 34 also swings forward, and when the second link member 41 moves rearward, the swing member 34 swings backward in conjunction with this movement.

  Thus, even when the link mechanism is configured by the first link member 40 and the second link member 41 instead of the linear motion member 32 of the second embodiment, the same effect as that of the second embodiment is obtained. Can do.

(Fifth embodiment)
A fifth embodiment of the present invention will be described. As shown in FIGS. 10 and 11, the characteristic point of this embodiment is that the forward / backward fixing portion 31 and the linear motion member 32 are fixed and the brake means 36 is swung via the switching member 42. Note that the basic configuration of the present embodiment is not different from that of the first embodiment, and therefore, only the portions that are different from the first embodiment will be described while avoiding redundant description.

As shown in FIGS. 10 and 11, the linear motion member 32 according to the present embodiment has the receiving portion 32a fixed to the engaging portion 31a. When moving forward, the receiving portion 32a is pushed forward by the engaging portion 31a, and when the torsion motor 21 reverses and the advance / retreat fixing portion 31 moves backward, the receiving portion 32a is engaged with the engaging portion 31a. To be pushed backward.
A switching member 42 is attached to the rotating shaft 35 of this embodiment instead of attaching the brake means 36.

  The switching member 42 is a member that swings about the rotation shaft 35 and includes a pressing portion 42 a for contacting and moving the brake means 36. The pressing portion 42a is disposed so as to face a pressed portion 36b of the brake means 36, which will be described later, and is engaged with the pressed portion 36b of the brake means 36 when the switching member 42 swings in the direction of the brake means 36. It is possible. The switching member 42 rotates integrally with the rotation shaft 35. For this reason, as shown in FIG. 11, the switching member 42 swings in a direction to engage the pressed portion 36 b of the brake means 36 in conjunction with the swinging member 34 swinging forward. Further, the switching member 42 swings in the direction in which the engagement with the pressed portion 36b of the brake means 36 is released in conjunction with the swinging member 34 swinging backward.

The brake means 36 according to the present embodiment is rotatably attached to a support shaft 43 provided separately from the rotation shaft 35. The brake means 36 includes a pressed portion 36b that can come into contact with the pressing portion 42a of the switching member 42. When the pressing portion 42a of the switching member 42 acts on the pressed portion 36b, the brake means 36 becomes a wire reel. It is comprised so that it may rock | fluctuate in the direction from which engagement with 13 is cancelled | released, and will take a standby state.
The brake mechanism 30 described above operates as follows (see FIG. 11).

  First, the trigger of the reinforcing bar binding machine 10 is operated to perform a twisting operation. At this time, the torsion motor 21 rotates in the forward rotation direction. With this rotation, the advance / retreat fixing portion 31 moves in the forward direction together with the advance / retreat cylinder portion 24. When the advance / retreat fixing portion 31 moves, the linear motion member 32 fixed to the advance / retreat fixing portion 31 moves, and the swing member 34 and the switching member 42 swing forward. This movement eliminates the force that has pushed the pressed portion 36 b of the brake means 36 by the pressing portion 42 a of the switching member 42, so that the brake means 36 is engaged with the wire reel 13 by the urging force of the engagement urging means 37. Swing in the direction. As described above, the torsion motor 21 as the power source drives the forward / backward fixing portion 31 as the transmission member in the forward direction to engage the brake means 36 with the wire reel 13. When the brake means 36 is engaged with the wire reel 13, the rotation of the wire reel 13 that has been rotated by inertia can be stopped.

  In addition, when the brake means 36 swings, the claw portion 36a of the brake means 36 may not enter the engagement portion 13b of the wire reel 13 and the claw portion 36a may contact the protruding portion 13c of the wire reel 13. is there. If the claw portion 36a is forcibly pressed against the wire reel 13 in such a state, the brake means 36 and the wire reel 13 may be locked, resulting in a malfunction. However, according to the present embodiment, the brake means 36 swings in the direction in which the brake means 36 is engaged with the wire reel 13 by the urging force of the engagement urging means 37, so that the engagement urging means is applied when a certain load is applied. 37 can be elastically deformed to release the force. As described above, since the buffer mechanism is provided for elastically buffering so that an excessive load is not applied to the brake means 36, excessive input by the transmission member is prevented from occurring or even when excessive input by the transmission member is generated. A buffer mechanism can absorb excess input.

  When the wire reel 13 is stopped by the operation as described above and the twisting operation is finished, the torsion motor 21 is reversely rotated, and the advance / retreat fixing portion 31 moves in the backward direction together with the advance / retreat cylinder portion 24 by this rotation. When the advance / retreat fixing portion 31 moves, the linear motion member 32 fixed to the advance / retreat fixing portion 31 moves, and the swinging member 34 and the switching member 42 swing backward. By this movement, the pressing portion 42a of the switching member 42 presses the pressed portion 36b of the brake means 36, so that the engagement with the wire reel 13 is released against the urging force of the engagement urging means 37. And the brake means 36 swings. Thus, the torsion motor 21 as the power source drives the forward / backward fixing portion 31 as the transmission member in the backward direction to release the brake means 36 from the wire reel 13. Then, the torsion motor 21 rotates until the standby state as shown in FIG.

(Sixth embodiment)
A sixth embodiment of the present invention will be described. As shown in FIGS. 12 and 13, the characteristic point of the present embodiment is that the advance / retreat fixing portion 31 and the linear motion member 32 are separated without being fixed. Since the basic configuration of the present embodiment is not different from that of the fifth embodiment, only the differences from the fifth embodiment will be described while avoiding redundant description.

As shown in FIGS. 12 and 13, in the linear motion member 32 according to the present embodiment, since the receiving portion 32 a is provided behind the engaging portion 31 a, the torsion motor 21 is reversely rotated to advance and retract. When 31 moves rearward, the receiving portion 32a is pushed by the engaging portion 31a. However, when the torsion motor 21 rotates forward and the advance / retreat fixing portion 31 moves forward, the receiving portion 32a is engaged with the engaging portion. It is not pushed by 31a.
The brake mechanism 30 described above operates as follows (see FIG. 13).

  First, the trigger of the reinforcing bar binding machine 10 is operated to perform a twisting operation. At this time, the torsion motor 21 rotates in the forward rotation direction. With this rotation, the advance / retreat fixing portion 31 moves in the forward direction together with the advance / retreat cylinder portion 24. Due to this movement, the force that has pushed the receiving portion 32a of the linear motion member 32 by the engaging portion 31a of the advance / retreat fixing portion 31, and the force that has pushed the pressed portion 36b of the brake means 36 by the pressing portion 42a of the switching member 42. Therefore, the urging force of the engagement urging means 37 swings the brake means 36 in a direction to engage with the wire reel 13. As described above, the torsion motor 21 as the power source drives the forward / backward fixing portion 31 as the transmission member in the forward direction to engage the brake means 36 with the wire reel 13. When the brake means 36 is engaged with the wire reel 13, the rotation of the wire reel 13 that has been rotated by inertia can be stopped.

  In addition, when the brake means 36 swings, the claw portion 36a of the brake means 36 may not enter the engagement portion 13b of the wire reel 13 and the claw portion 36a may contact the protruding portion 13c of the wire reel 13. is there. If the claw portion 36a is forcibly pressed against the wire reel 13 in such a state, the brake means 36 and the wire reel 13 may be locked, resulting in a malfunction. However, according to the present embodiment, the brake means 36 swings in the direction in which the brake means 36 is engaged with the wire reel 13 by the urging force of the engagement urging means 37, so that the engagement urging means is applied when a certain load is applied. 37 can be elastically deformed to release the force. As described above, since the buffer mechanism is provided for elastically buffering so that an excessive load is not applied to the brake means 36, excessive input by the transmission member is prevented from occurring or even when excessive input by the transmission member is generated. A buffer mechanism can absorb excess input.

  When the wire reel 13 is stopped by the operation as described above and the twisting operation is finished, the torsion motor 21 is reversely rotated, and the advance / retreat fixing portion 31 moves in the backward direction together with the advance / retreat cylinder portion 24 by this rotation. By this movement, the engaging portion 31a of the advance / retreat fixing portion 31 pushes the receiving portion 32a of the linear motion member 32, so that the swing member 34 and the switching member 42 swing backward. By this movement, the pressing portion 42a of the switching member 42 presses the pressed portion 36b of the brake means 36, so that the engagement with the wire reel 13 is released against the urging force of the engagement urging means 37. And the brake means 36 swings. Thus, the torsion motor 21 as the power source drives the forward / backward fixing portion 31 as the transmission member in the backward direction to release the brake means 36 from the wire reel 13. Then, the torsion motor 21 rotates until the standby state as shown in FIG.

(Seventh embodiment)
A seventh embodiment of the present invention will be described. The characteristic point of this embodiment is that the brake means 36 is swung via the switching member 42 as shown in FIGS. Since the basic configuration of the present embodiment is not different from that of the second embodiment, only the differences from the second embodiment will be described while avoiding redundant description.
A switching member 42 is attached to the rotating shaft 35 of this embodiment instead of attaching the brake means 36.

  The switching member 42 is a member that swings about the rotation shaft 35 and includes a pressing portion 42 a for contacting and moving the brake means 36. The pressing portion 42a is disposed so as to face a pressed portion 36b of the brake means 36, which will be described later, and is engaged with the pressed portion 36b of the brake means 36 when the switching member 42 swings in the direction of the brake means 36. It is possible. The switching member 42 rotates integrally with the rotation shaft 35. Therefore, as shown in FIG. 15, the switching member 42 moves in a direction in which the engagement with the pressed portion 36 b of the brake means 36 is released in conjunction with the swinging member 34 swinging forward. Swing. Further, the switching member 42 swings in a direction to engage with the pressed portion 36 b of the brake means 36 in conjunction with the swinging member 34 swinging backward.

The brake means 36 according to the present embodiment is rotatably attached to a support shaft 43 provided separately from the rotation shaft 35. The brake means 36 includes a pressed portion 36b that can come into contact with the pressing portion 42a of the switching member 42. When the pressing portion 42a of the switching member 42 acts on the pressed portion 36b, the brake means 36 becomes a wire reel. 13 is configured to swing in a direction to engage with.
The brake mechanism 30 described above operates as follows (see FIG. 15).

  First, the trigger of the reinforcing bar binding machine 10 is operated to perform a twisting operation. At this time, the torsion motor 21 rotates in the forward rotation direction. With this rotation, the advance / retreat fixing portion 31 moves in the forward direction together with the advance / retreat cylinder portion 24. When the advance / retreat cylinder portion 24 moves forward, the engaging portion 31a of the advance / retreat fixing portion 31 pulls up the receiving portion 32a of the linear motion member 32, and the swing member 34 and the switching member 42 swing forward. By this movement, the pressing portion 42a of the switching member 42 pushes the pressed portion 36b of the brake means 36, so that the brake means 36 is engaged in the direction in which it engages with the wire reel 13 against the urging force of the release urging means 38. Swing. As described above, the torsion motor 21 as the power source drives the forward / backward fixing portion 31 as the transmission member in the forward direction to engage the brake means 36 with the wire reel 13. When the brake means 36 is engaged with the wire reel 13, the rotation of the wire reel 13 that has been rotated by inertia can be stopped.

  When the wire reel 13 is stopped by the operation as described above and the twisting operation is finished, the torsion motor 21 is reversely rotated, and the advance / retreat fixing portion 31 moves in the backward direction together with the advance / retreat cylinder portion 24 by this rotation. Due to this movement, the force that the engaging part 31a of the advance / retreat fixing part 31 pulled up the receiving part 32a of the linear movement member 32 and the force that pushed the pressed part 36b of the brake means 36 by the pressing part 42a of the switching member 42. Therefore, the urging force of the release urging means 38 swings the brake means 36 in the direction in which the engagement with the wire reel 13 is released. Then, the torsion motor 21 rotates until the standby state as shown in FIG.

  When the brake means 36 swings in the direction in which the engagement with the wire reel 13 is released, the brake means 36 interferes with a foreign matter or the like that has entered the inside of the machine, and the brake means 36 is prevented from swinging. There is a case. If the brake means 36 is forcibly swung in such a state, the brake means 36 may be locked, resulting in malfunction. However, according to the present embodiment, the brake means 36 is swung in the direction in which the engagement with the wire reel 13 is released by the urging force of the release urging means 38, so that it is released when a certain load is applied. The biasing means 38 can be elastically deformed to release the force. As described above, since the buffer mechanism is provided for elastically buffering so that an excessive load is not applied to the brake means 36, excessive input by the transmission member is prevented from occurring or even when excessive input by the transmission member is generated. A buffer mechanism can absorb excess input.

(Eighth embodiment)
An eighth embodiment of the present invention will be described. The characteristic point of this embodiment is that the brake means 36 and the switching member 42 are provided coaxially as shown in FIG. Since the basic configuration of the present embodiment is not different from that of the fifth embodiment, only the differences from the fifth embodiment will be described while avoiding redundant description.

A brake means 36 and a switching member 42 are attached to the rotating shaft 35 of the present embodiment. The switching member 42 rotates integrally with the rotation shaft 35. On the other hand, the brake means 36 is rotatably attached to the rotation shaft 35. For this reason, when the rotating shaft 35 is rotated by the swinging of the swinging member 34, the switching member 42 rotates together with the rotating shaft 35. However, if the brake means 36 is not pushed by the switching member 42, the rotating shaft 35 is not affected by the rotation of 35.
Thus, even when the brake means 36 and the switching member 42 are provided coaxially, the same effect as that of the fifth embodiment can be obtained.

(Ninth embodiment)
A ninth embodiment of the present invention will be described. The feature point of this embodiment is that the brake means 36 and the switching member 42 are provided coaxially as shown in FIG. Note that the basic configuration of the present embodiment is not different from that of the sixth embodiment, and therefore, only the portions that are different from the sixth embodiment will be described while avoiding redundant description.

A brake means 36 and a switching member 42 are attached to the rotating shaft 35 of the present embodiment. The switching member 42 rotates integrally with the rotation shaft 35. On the other hand, the brake means 36 is rotatably attached to the rotation shaft 35. For this reason, when the rotating shaft 35 is rotated by the swinging of the swinging member 34, the switching member 42 rotates together with the rotating shaft 35. However, if the brake means 36 is not pushed by the switching member 42, the rotating shaft 35 is not affected by the rotation of 35.
Thus, even when the brake means 36 and the switching member 42 are provided coaxially, the same effect as in the sixth embodiment can be obtained.

(Tenth embodiment)
A tenth embodiment of the present invention will be described. The characteristic point of this embodiment is that the brake means 36 and the switching member 42 are provided coaxially as shown in FIG. Note that the basic configuration of the present embodiment is not different from that of the seventh embodiment, and therefore, only the portions that are different from the seventh embodiment will be described while avoiding redundant description.

A brake means 36 and a switching member 42 are attached to the rotating shaft 35 of the present embodiment. The switching member 42 rotates integrally with the rotation shaft 35. On the other hand, the brake means 36 is rotatably attached to the rotation shaft 35. For this reason, when the rotating shaft 35 is rotated by the swinging of the swinging member 34, the switching member 42 rotates together with the rotating shaft 35. However, if the brake means 36 is not pushed by the switching member 42, the rotating shaft 35 is not affected by the rotation of 35.
Thus, even when the brake means 36 and the switching member 42 are provided coaxially, the same effect as that of the seventh embodiment can be obtained.

(Eleventh embodiment)
An eleventh embodiment of the present invention will be described. As shown in FIG. 19, the feature of this embodiment is that a first link member 40 and a second link member 41 are provided instead of the linear motion member 32 of the fifth embodiment. Since the basic configuration of the present embodiment is not different from that of the fifth embodiment, only the differences from the fifth embodiment will be described while avoiding redundant description.

  The 1st link member 40 is a member attached so that rotation was possible centering on the rotation fulcrum 40b. The first link member 40 includes a receiving portion 40a that is rotatably connected to the engaging portion 31a of the advance / retreat fixing portion 31, and a joint portion 40c that is rotatably connected to the second link member 41. ing. The first link member 40 rotates in conjunction with the advance / retreat fixing portion 31 when the advance / retreat fixing portion 31 moves.

  The second link member 41 is a member rotatably connected to the first link member 40 at the joint portion 40c, and is configured to move back and forth in conjunction with the turning operation of the first link member 40. Yes. The second link member 41 has an end on the opposite side of the joint portion 40c connected to the swing member 34 by a connection pin 41a. When the second link member 41 moves forward, the second link member 41 swings in conjunction therewith. The member 34 also swings forward, and when the second link member 41 moves rearward, the swing member 34 swings backward in conjunction with this movement.

  Thus, even when the link mechanism is configured by the first link member 40 and the second link member 41 instead of the linear motion member 32 of the fifth embodiment, the same effect as that of the fifth embodiment is obtained. Can do.

(Twelfth embodiment)
A twelfth embodiment of the present invention will be described. As shown in FIG. 20, the characteristic point of this embodiment is that a first link member 40 and a second link member 41 are provided instead of the linear motion member 32 of the sixth embodiment. Note that the basic configuration of the present embodiment is not different from that of the sixth embodiment, and therefore, only the portions that are different from the sixth embodiment will be described while avoiding redundant description.

  The 1st link member 40 is a member attached so that rotation was possible centering on the rotation fulcrum 40b. The first link member 40 includes a receiving portion 40a that is rotatably connected to the engaging portion 31a of the advance / retreat fixing portion 31, and a joint portion 40c that is rotatably connected to the second link member 41. ing.

  The first link member 40 according to the present embodiment is moved when the receiving portion 40a is pushed by the engaging portion 31a when the advance / retreat fixing portion 31 moves. In the present embodiment, as shown in FIG. 20, since the receiving portion 40a is provided behind the engaging portion 31a, when the torsion motor 21 reverses and the advance / retreat fixing portion 31 moves rearward. The receiving portion 40a is pushed by the engaging portion 31a. However, when the torsion motor 21 rotates forward and the advance / retreat fixing portion 31 moves forward, the receiving portion 40a is not pushed by the engaging portion 31a. Yes.

  The second link member 41 is a member rotatably connected to the first link member 40 at the joint portion 40c, and is configured to move back and forth in conjunction with the turning operation of the first link member 40. Yes. The second link member 41 has an end on the opposite side of the joint portion 40c connected to the swing member 34 by a connection pin 41a. When the second link member 41 moves forward, the second link member 41 swings in conjunction therewith. The member 34 also swings forward, and when the second link member 41 moves rearward, the swing member 34 swings backward in conjunction with this movement.

  Thus, even when the link mechanism is configured by the first link member 40 and the second link member 41 instead of the linear motion member 32 of the sixth embodiment, the same effect as that of the sixth embodiment is obtained. Can do.

(13th Embodiment)
A thirteenth embodiment of the present invention will be described. As shown in FIG. 21, the characteristic point of this embodiment is that a first link member 40 and a second link member 41 are provided instead of the linear motion member 32 of the seventh embodiment. Note that the basic configuration of the present embodiment is not different from that of the seventh embodiment, and therefore, only the portions that are different from the seventh embodiment will be described while avoiding redundant description.

  The 1st link member 40 is a member attached so that rotation was possible centering on the rotation fulcrum 40b. The first link member 40 includes a receiving portion 40a that is rotatably connected to the engaging portion 31a of the advance / retreat fixing portion 31, and a joint portion 40c that is rotatably connected to the second link member 41. ing.

  The first link member 40 according to the present embodiment is moved when the receiving portion 40a is pushed by the engaging portion 31a when the advance / retreat fixing portion 31 moves. In the present embodiment, as shown in FIG. 20, since the receiving portion 40a is provided in front of the engaging portion 31a, the torsion motor 21 rotates forward and the advance / retreat fixing portion 31 moves forward. Sometimes, the receiving portion 40a is pushed by the engaging portion 31a. However, when the torsion motor 21 reverses and the advance / retreat fixing portion 31 moves backward, the receiving portion 40a is not pushed by the engaging portion 31a. Yes.

  The second link member 41 is a member rotatably connected to the first link member 40 at the joint portion 40c, and is configured to move back and forth in conjunction with the turning operation of the first link member 40. Yes. The second link member 41 has an end on the opposite side of the joint portion 40c connected to the swing member 34 by a connection pin 41a. When the second link member 41 moves forward, the second link member 41 swings in conjunction therewith. The member 34 also swings forward, and when the second link member 41 moves rearward, the swing member 34 swings backward in conjunction with this movement.

  Thus, even when the link mechanism is configured by the first link member 40 and the second link member 41 instead of the linear motion member 32 of the seventh embodiment, the same effect as that of the seventh embodiment is obtained. Can do.

(Fourteenth embodiment)
A fourteenth embodiment of the present invention will be described. The characteristic point of this embodiment is that the brake means 36 and the switching member 42 are provided coaxially as shown in FIG. Since the basic configuration of the present embodiment is not different from that of the eleventh embodiment, only the differences from the eleventh embodiment will be described while avoiding redundant description.

A brake means 36 and a switching member 42 are attached to the rotating shaft 35 of the present embodiment. The switching member 42 rotates integrally with the rotation shaft 35. On the other hand, the brake means 36 is rotatably attached to the rotation shaft 35. For this reason, when the rotating shaft 35 is rotated by the swinging of the swinging member 34, the switching member 42 rotates together with the rotating shaft 35. However, if the brake means 36 is not pushed by the switching member 42, the rotating shaft 35 is not affected by the rotation of 35.
Thus, even when the brake means 36 and the switching member 42 are provided coaxially, the same effect as in the eleventh embodiment can be obtained.

(Fifteenth embodiment)
A fifteenth embodiment of the present invention will be described. The feature point of this embodiment is that the brake means 36 and the switching member 42 are provided coaxially as shown in FIG. Since the basic configuration of the present embodiment is not different from that of the twelfth embodiment, only the portions that are different from the twelfth embodiment will be described while avoiding repeated description.

A brake means 36 and a switching member 42 are attached to the rotating shaft 35 of the present embodiment. The switching member 42 rotates integrally with the rotation shaft 35. On the other hand, the brake means 36 is rotatably attached to the rotation shaft 35. For this reason, when the rotating shaft 35 is rotated by the swinging of the swinging member 34, the switching member 42 rotates together with the rotating shaft 35. However, if the brake means 36 is not pushed by the switching member 42, the rotating shaft 35 is not affected by the rotation of 35.
Thus, even when the brake means 36 and the switching member 42 are provided coaxially, the same effect as that of the twelfth embodiment can be obtained.

(Sixteenth embodiment)
A sixteenth embodiment of the present invention will be described. The characteristic point of this embodiment is that the brake means 36 and the switching member 42 are provided coaxially as shown in FIG. Since the basic configuration of the present embodiment is not different from that of the thirteenth embodiment, only the differences from the thirteenth embodiment will be described while avoiding redundant description.

A brake means 36 and a switching member 42 are attached to the rotating shaft 35 of the present embodiment. The switching member 42 rotates integrally with the rotation shaft 35. On the other hand, the brake means 36 is rotatably attached to the rotation shaft 35. For this reason, when the rotating shaft 35 is rotated by the swinging of the swinging member 34, the switching member 42 rotates together with the rotating shaft 35. However, if the brake means 36 is not pushed by the switching member 42, the rotating shaft 35 is not affected by the rotation of 35.
Thus, even when the brake means 36 and the switching member 42 are provided coaxially, the same effect as that of the thirteenth embodiment can be obtained.

(Seventeenth embodiment)
A seventeenth embodiment of the present invention will be described. The characteristic point of this embodiment is that the buffer mechanism is configured by making the brake means 36 elastically deformable. Note that the basic configuration of the present embodiment is not different from that of the first embodiment, and therefore, only the portions that are different from the first embodiment will be described while avoiding redundant description.

  In the present embodiment, as shown in FIGS. 25 and 26, the advance / retreat fixing portion 31 and the linear motion member 32 are fixed, and a buffer is provided on the path for transmitting the power of the torsion motor 21 to the brake means 36. No mechanism is provided.

  However, as shown in FIG. 27, the brake means 36 according to the present embodiment is formed to be elastically deformable. That is, the brake means 36 according to the present embodiment includes a base portion 36c supported by the rotating shaft 35, an intermediate portion 36d connected to the base portion 36c, and a distal end portion 36e connected to the intermediate portion 36d. This part can be bent elastically. In the present embodiment, the first swinging node 36 f between the base portion 36 c and the intermediate portion 36 d can be bent in a direction in which the claw portion 36 a at the tip is separated from the wire reel 13. A first urging member 36h is attached to the first swinging node 36f so that the base portion 36c and the intermediate portion 36d are straight without bending (in other words, the brake means 36 is connected to the wire reel 13). (In the direction of engagement). The second swinging node 36g between the intermediate portion 36d and the tip portion 36e can be bent in a direction in which the tip claw portion 36a approaches the wire reel 13. A second urging member 36i is attached to the second swinging node 36g so that the intermediate portion 36d and the tip portion 36e are straight without bending (in other words, the brake means 36 is connected to the wire reel 13). (Toward the direction of disengagement).

  As described above, the brake means 36 includes the first swinging node 36f that can be bent in a direction away from the wire reel 13 and the second swinging node 36g that can be bent in a direction approaching the wire reel 13. Since it can be bent against the urging member attached to the swinging node, the brake means 36 is not excessively loaded.

  For example, as shown in FIG. 27B, when the brake means 36 swings in the direction in which it engages with the wire reel 13, the claw part 36a of the brake means 36 enters the engagement part 13b of the wire reel 13 well. In some cases, the claw portion 36 a may come into contact with the protruding portion 13 c of the wire reel 13. If the claw portion 36a is forcibly pressed against the wire reel 13 in such a state, the brake means 36 and the wire reel 13 may be locked, resulting in a malfunction. However, in this embodiment, when a certain load is applied, the brake means 36 bends at the first swinging node 36f against the urging force of the first urging member 36h, and the force can be released. As described above, since the buffer mechanism that elastically buffers the brake means 36 so as not to apply an excessive load is provided, the buffer mechanism can absorb the excessive input even when the input by the transmission member occurs.

  Further, as shown in FIG. 28B, when the brake means 36 swings in the direction in which the engagement with the wire reel 13 is released, the brake means 36 interferes with foreign matter E or the like that has entered the machine. However, the swinging of the brake means 36 may be hindered. If the brake means 36 is forcibly swung in such a state, the brake means 36 may be locked, resulting in malfunction. However, in this embodiment, when a certain load is applied, the brake means 36 bends at the second swinging node 36g against the urging force of the second urging member 36i, and the force can be released. As described above, since the buffer mechanism that elastically buffers the brake means 36 so as not to apply an excessive load is provided, the buffer mechanism can absorb the excessive input even when the input by the transmission member occurs.

  The brake means 36 of FIGS. 25 and 26 is different in shape from the brake means 36 of FIG. 27. However, this is for the convenience of the drawing, and the brake means 36 of FIGS. This is the same as the brake means 36.

(Eighteenth embodiment)
An eighteenth embodiment of the present invention will be described. The feature of this embodiment is that the brake means 36 can be elastically deformed by a method different from that of the seventeenth embodiment. Note that the basic configuration of the present embodiment is not different from that of the seventeenth embodiment, and therefore, only the portions that are different from the seventeenth embodiment will be described while avoiding redundant description.

  The brake means 36 according to the present embodiment is formed of an elastically deformable material such as a soft metal or a synthetic resin. The brake means 36 is configured such that the claw portion 36a of the wire reel 13 is at least in a state in which the advance / retreat fixing portion 31 (transmission member) is maximum displaced in the engagement direction (in other words, the state in which the torsion hook 25 has finished the torsion operation). What is necessary is just to be elastically deformable to such an extent that it does not lock even if it is pressed against the protrusion 13c. Thus, by making the brake means 36 elastically deformable, the brake means 36 can be prevented from locking.

  For example, as shown in FIG. 29 (b), when the brake means 36 swings in the direction in which it engages with the wire reel 13, the claw part 36 a of the brake means 36 enters the engagement part 13 b of the wire reel 13 well. In some cases, the claw portion 36 a may come into contact with the protruding portion 13 c of the wire reel 13. If the claw portion 36a is forcibly pressed against the wire reel 13 in such a state, the brake means 36 and the wire reel 13 may be locked, resulting in a malfunction. However, in this embodiment, when a certain load is applied, the brake means 36 can be elastically deformed to release the force.

  Further, as shown in FIG. 30 (b), when the brake means 36 swings in the direction in which the engagement with the wire reel 13 is released, the brake means 36 interferes with foreign matter E that has entered the machine. However, the swinging of the brake means 36 may be hindered. If the brake means 36 is forcibly swung in such a state, the brake means 36 may be locked, resulting in malfunction. However, in this embodiment, when a certain load is applied, the brake means 36 can be elastically deformed to release the force.

(Nineteenth embodiment)
A nineteenth embodiment of the present invention will be described. The feature of this embodiment is that the brake means 36 can be elastically deformed by a method different from that of the seventeenth embodiment. Note that the basic configuration of the present embodiment is not different from that of the seventeenth embodiment, and therefore, only the portions that are different from the seventeenth embodiment will be described while avoiding redundant description.

  The brake means 36 according to the present embodiment includes an elastic deformation portion 36j that is more easily elastically deformed than other portions, and at least the state in which the advance / retreat fixing portion 31 (transmission member) is displaced maximum in the engagement direction (in other words, In a state where the torsion hook 25 has finished the twisting operation), the claw portion 36a can be elastically deformed to the extent that it does not lock even if it is pressed against the protruding portion 13c of the wire reel 13. For example, the elastic deformation portion 36j is formed by winding a part of the brake means 36 in a coil shape. Thus, by making the brake means 36 elastically deformable, the brake means 36 can be prevented from locking.

  For example, as shown in FIG. 31 (b), when the brake means 36 swings in a direction to engage with the wire reel 13, the claw part 36 a of the brake means 36 enters the engagement part 13 b of the wire reel 13 well. In some cases, the claw portion 36 a may come into contact with the protruding portion 13 c of the wire reel 13. If the claw portion 36a is forcibly pressed against the wire reel 13 in such a state, the brake means 36 and the wire reel 13 may be locked, resulting in a malfunction. However, in this embodiment, when a certain load is applied, the brake means 36 can be elastically deformed to release the force.

  Further, as shown in FIG. 32B, when the brake means 36 swings in a direction in which the engagement with the wire reel 13 is released, the brake means 36 interferes with foreign matter E or the like that has entered the machine. However, the swinging of the brake means 36 may be hindered. If the brake means 36 is forcibly swung in such a state, the brake means 36 may be locked, resulting in malfunction. However, in this embodiment, when a certain load is applied, the brake means 36 can be elastically deformed to release the force.

(20th embodiment)
A twentieth embodiment of the present invention will be described. The characteristic point of this embodiment is that the buffer mechanism is configured by elastically receiving the power transmitted by the advance / retreat fixing portion 31 (transmission member). Note that the basic configuration of the present embodiment is not different from that of the seventeenth embodiment, and therefore, only the portions that are different from the seventeenth embodiment will be described while avoiding redundant description.

  As shown in FIG. 33, the linear motion member 32 according to this embodiment includes receiving portions 32 a on both sides of the engaging portion 31 a of the advance / retreat fixing portion 31. And the buffer spring 44 is provided between each receiving part 32a and the engaging part 31a. For this reason, the power transmitted by the advance / retreat fixing portion 31 is transmitted to the linear motion member 32 via the buffer spring 44. Thus, by receiving the power transmitted by the advance / retreat fixing portion 31 elastically, it is possible to prevent an excessive load from being applied to the brake means 36.

(Modifications of Embodiments 17-20)
In the above-described seventeenth to twentieth embodiments, the brake mechanism 30 is configured using the linear motion member 32, but as shown in FIG. 34, the first link member 40 and the second link member 40 are used instead of the linear motion member 32. A link member 41 may be used.

(Other)
In the first to twentieth embodiments described above, a clutch mechanism 50 as shown in FIG. 35 may be used. The clutch mechanism 50 is disposed on a path for transmitting the power of the torsion motor 21 to the brake means 36. For example, it can be arranged instead of the gear 22.

The clutch mechanism 50 is disposed within the shaft 51 that is an input shaft, a clutch plate 52 that rotates integrally with the shaft 51, a clutch gear 53 that is pivotally supported by the shaft 51, and the clutch gear 53. A ball 54 and a clutch spring 55 are provided.
The shaft 51 is directly or indirectly connected to the output shaft of the torsion motor 21 and rotates in conjunction with the rotation of the torsion motor 21.

  The clutch plate 52 is a disk member that is press-fitted and fixed to the shaft 51, and is provided with a plurality of engagement recesses 52a in the circumferential direction. The engaging recess 52a has a smaller diameter than the inner diameter of the ball 54, and the ball 54 can be fitted therein.

  The clutch gear 53 is a gear that is pivotally supported by the shaft 51 and relays the rotational force of the shaft 51 downstream in the transmission path. Inside the clutch gear 53, a guide hole 53a having a diameter substantially the same as the inner diameter of the ball 54 and slidably receiving the ball 54 is formed. A clutch spring 55 that urges the ball 54 outward is disposed inside the guide hole 53a. The ball 54 is urged outward by the clutch spring 55, thereby fitting into the engagement recess 52 a of the clutch plate 52.

  The clutch mechanism 50 operates as follows. First, the shaft 51 is rotated by a power source such as the torsion motor 21. When the shaft 51 rotates, the clutch plate 52 press-fitted and fixed to the shaft 51 also rotates integrally. The rotational force of the clutch plate 52 is transmitted to the clutch gear 53 via the ball 54, and the clutch gear 53 rotates.

However, if a load exceeding a certain level is applied to the output-side clutch gear 53 because the brake means 36 interferes with foreign matter, the ball 54 resists the urging force of the clutch spring 55 and moves inward of the guide hole 53a. evacuate. When the ball 54 is retracted, the engagement between the ball 54 and the engaging recess 52a is released, and power is not transmitted from the input side clutch plate 52 to the output side clutch gear 53. Thus, by providing the clutch mechanism 50, the power transmission path can be cut off when a certain load is applied, so that an excessive load is not applied to the brake means 36.
As described above, the buffer mechanism may be configured by the clutch mechanism 50 instead of the elastic load absorbing mechanism.

(Summary)
As described above, the torsion motor 21 that is a power source drives the forward / backward fixing portion 31 that is a transmission member in the forward direction when the brake means 36 is engaged with the wire reel 13, and the brake means 36 is connected to the wire reel. When the engagement is released from 13, the forward / backward fixing portion 31 which is a transmission member is driven in the backward direction, so that the transmission member can repeatedly input to the brake means 36 in both cases of engagement and disengagement. Absent. Therefore, the problem that the durability of the component is reduced and the noise is increased due to repeated impact on the component does not occur. Further, since it is not necessary to consider the size and arrangement of the gears, the brake mechanism 30 can be arranged by effectively utilizing the limited space.

  By the way, when the transmission member is moved forward or backward, even when the brake means 36 is locked due to foreign matter mixed in or a displacement of the engagement portion, the transmission member tries to operate the brake means 36 as it is, so that the brake means 36 May be overloaded. However, according to the present embodiment, since the shock absorbing mechanism for absorbing the load is provided so that the brake means 36 does not apply an excessive load, the excessive input by the transmission member is prevented or the excessive input by the transmission member is prevented. Even if it occurs, excess input can be absorbed by the buffer mechanism.

  A moving member (for example, the linear member 32, the swinging member 34, the first link member 40 in the above-described embodiment, and the like) disposed on the power transmission path from the power source (torsion motor 21) to the brake means 36. If there is a concern about an increase in sliding resistance or occurrence of sliding failure in the second link member 41 or the like, it is desirable to provide a buffer mechanism near the brake mechanism 30. The reason is that if a shock absorbing mechanism is provided between the part where the sliding resistance is increased and the power source, the power is absorbed by the shock absorbing mechanism even if the power source generates a large force. In some cases, the force of the power source is not transmitted to the increased portion, and the brake mechanism 30 cannot be operated against the sliding resistance. On the other hand, if the buffer mechanism is arranged downstream of the power transmission path (that is, near the brake mechanism 30) rather than the portion where the resistance is likely to increase, the force of the power source is reliably transmitted to the portion where the sliding resistance is increased. Thus, it is possible to make it difficult for the brake mechanism 30 to malfunction.

  By the way, the above-mentioned sliding failure may occur due to rust generated on the members inside the housing. That is, most of the brake mechanism 30 is disposed inside the housing, but the brake member 36 is attached so as to pass through the opening of the housing and be exposed to the outside. Therefore, there is a possibility that water or the like may enter the housing from the opening, but the moisture that has entered the housing is difficult to dry, and thus rust is likely to occur in the members inside the housing. In other words, it is inside the housing that the sliding resistance is likely to increase. Therefore, if the shock absorbing mechanism is provided on the brake mechanism 30 side of the housing opening, preferably on the outside of the housing, even if the sliding resistance on the transmission path is increased due to the occurrence of rust, it is less susceptible to the effect. A structure in which defects do not easily occur can be obtained.

  Further, an engagement urging means 37 that urges the brake means 36 in a direction to engage with the wire reel 13 is provided to constitute the buffer mechanism, and the brake means 36 is connected to the engagement urging means 37. If the brake means 36 is engaged with the wire reel 13 by moving in the direction in which the engagement with the wire reel 13 is released against the urging force, the engagement urging means 37 The brake means 36 acts on the wire reel 13 elastically using the urging force. Therefore, even when the brake means 36 is pressed against the protrusion 13c without entering the engagement portion 13b of the wire reel 13, the engagement biasing means 37 is elastically deformed so that the brake means 36 and the wire reel 13 are locked. Can be avoided.

  Further, the buffer mechanism is configured by including a release urging means 38 for urging the brake means 36 in a direction in which the engagement with the wire reel 13 is released, and the brake means 36 is configured to be the release urging means. When the engagement between the brake means 36 and the wire reel 13 is released, the release urging means 38 can be moved in a direction to engage with the wire reel 13 against the urging force of the release force 38. Using the urging force, the brake means 36 moves away from the wire reel 13. Therefore, even when a foreign matter or the like that has entered the machine interferes with the brake means 36 and the brake means 36 cannot move in the direction away from the wire reel 13, the release biasing means 38 is elastically deformed to cause the brake means 36 to move. Locking can be avoided.

  If the buffer mechanism is configured by making the brake means 36 elastically deformable, the brake means 36 can be prevented from being locked by elastically deforming the brake means 36 itself.

  Further, if the torsion motor 21 for driving the torsion hook 25 for twisting and binding the binding wire W is used as the power source, the brake means can be used without using the power source for the brake mechanism 30. 36 can be activated.

Further, if the transmission member moves forward or backward in conjunction with the forward or backward movement of the twisting hook 25, the difference between the rotational speed of the torsion motor 21 during normal rotation and the rotational speed during reverse rotation is conscious. There is no need to do. That is, the torsion motor 21 can be used for the brake mechanism 30 only by retrofitting the brake mechanism 30 to the conventional torsion mechanism 20 without any particular change on the torsion mechanism 20 side.
In the above-described embodiment, the torsion motor 21 is used as a power source. However, the present invention is not limited to this, and a power source different from the torsion motor 21 may be used.

  In the above-described embodiment, the brake means 36 is directly engaged with the wire reel 13. However, the present invention is not limited to this, and the brake means 36 may indirectly stop the wire reel 13. For example, the brake means 36 may indirectly stop the wire reel 13 by the brake means 36 acting on a member that rotates integrally with the wire reel 13. That is, the engagement in the present embodiment includes not only a configuration in which the claw portion or the like is locked to the concave and convex portions, but also a configuration in which the planar members are brought into contact with each other and stopped by friction.

(About friction brake)
In the above-described embodiment, the brake means 36 is engaged with the wire reel 13 having the substantially saw-toothed flange 13a. However, the present invention is not limited to this mode. Etc. may be used.

(Example 1 of friction brake)
For example, in the friction brake example 1 shown in FIGS. 36 and 37, the brake means 36 presses the friction surface 56 to stop the rotation of the wire reel 13.

  As shown in FIG. 37, the wire reel 13 according to the first example has a circular peripheral edge of the flange 13a, and does not include the engagement portion 13b and the protruding portion 13c that are substantially saw-tooth shaped. In other words, in this example 1, the concave and convex portions are not provided at the locations where the brake means 36 is engaged.

  The brake means 36 according to the first example includes a friction surface 56 at the tip. The friction surface 56 is disposed so as to face the peripheral portion of the wire reel 13, and the friction surface 56 is pressed against the peripheral portion of the wire reel 13 when the brake means 36 swings in the direction of the wire reel 13. It has become. The brake means 36 according to Example 1 does not include the claw portion 36a at the tip.

Although not particularly illustrated, a member for increasing the frictional force is attached to the peripheral portion of the wire reel 13 and the friction surface 56 of the brake means 36 that are engaged with each other, or a process for increasing the frictional force is performed. You may give it. This also applies to other embodiments using a friction brake.
According to such a configuration, the following effects can be obtained.

  That is, since the brake means 36 is a friction brake that presses the friction surface 56 to stop the rotation of the wire reel 13, the operation of the brake means 36 is compared with a structure in which the wire reel 13 and the brake means 36 are meshed with unevenness. Stroke can be reduced. By reducing the operating stroke of the brake means 36, the force generated by the brake means 36 can be increased by, for example, a lever, so that it is difficult to be affected by dust and rust.

  Further, when such a friction brake is used, there is no problem that the brake means 36 and the wire reel 13 are locked because the engagement is not successful in the structure in which the engagement is made with the unevenness. For example, in a structure that engages with unevenness, the claw portion 36a of the brake means 36 does not enter the engagement portion 13b of the wire reel 13, and the claw portion 36a is pressed against the protruding portion 13c of the wire reel 13 to cause the brake means 36. In addition, an excessive load is applied to the wire reel 13, which may cause malfunction. However, if it is a friction brake, an unreasonable load will not occur even if the brake means 36 and the wire reel 13 are engaged at any timing.

(Modified example of friction brake example 1)
In the friction brake example 1 described above, the advance / retreat fixing portion 31, the linear motion member 32, and the swing member 34 connect the advance / retreat cylinder portion 24 and the brake means 36. However, the present invention is not limited to this. For example, a connecting member including a link mechanism as shown in FIG. 38 may be used.
In the example shown in FIG. 38, the first link member 40 and the second link member 41 are provided in place of the linear motion member 32 of the friction brake example 1.

  The 1st link member 40 is a member attached so that rotation was possible centering on the rotation fulcrum 40b. The first link member 40 includes a receiving portion 40a that is rotatably connected to the engaging portion 31a of the advance / retreat fixing portion 31, and a joint portion 40c that is rotatably connected to the second link member 41. ing.

  The first link member 40 swings when the engaging portion 31a acts on the receiving portion 40a when the advance / retreat fixing portion 31 moves. Specifically, in the first link member 40, when the torsion motor 21 rotates in the forward direction and the advance / retreat cylinder portion 24 and the advance / retreat fixing portion 31 are sent forward, the receiving portion 40a swings forward and twists. When the motor 21 is reversely rotated and the advance / retreat cylinder portion 24 and the advance / retreat fixing portion 31 are sent backward, the receiving portion 40a swings backward. As described above, the first link member 40 swings forward or backward in conjunction with the advance / retreat operation of the advance / retreat cylinder portion 24.

  The second link member 41 is a member rotatably connected to the first link member 40 in the joint portion 40c, and is configured to swing back and forth in conjunction with the rotation operation of the first link member 40. ing. The second link member 41 has an end on the opposite side of the joint portion 40c connected to the swing member 34 by a connection pin 41a. When the second link member 41 swings forward, the second link member 41 swings in conjunction therewith. The moving member 34 also swings forward, and when the second link member 41 swings backward, the swinging member 34 swings backward in conjunction with this.

  Thus, even when the link mechanism is configured by the first link member 40 and the second link member 41 instead of the linear motion member 32, the same effect as that of the friction brake example 1 can be obtained.

(Example 2 of friction brake)
A friction brake example 2 will be described. The feature of Example 2 is that a friction brake different from the above-described structure is provided.

  As shown in FIG. 39, the brake mechanism 30 according to the second example includes an advance / retreat fixing portion 31 and a brake means 57. In the second example, the advance / retreat fixing portion 31 connects the advance / retreat cylinder portion 24 and the brake means 57.

  The advance / retreat fixing portion 31 is a transmission member for transmitting the power of the torsion motor 21 as a power source to the brake means 57. The advance / retreat fixing portion 31 is fixed to the advance / retreat cylinder portion 24 of the torsion mechanism 20, and moves forward or backward in conjunction with the advance / retreat operation of the advance / retreat cylinder portion 24. In other words, the advance / retreat fixing portion 31 moves forward integrally with the advance / retreat cylinder portion 24 when the torsion motor 21 rotates forward, and rearward integrally with the advance / retreat cylinder portion 24 when the torsion motor 21 reverses. To move to. The advancing / retreating fixing portion 31 is formed with a pin-shaped engaging portion 31 a for engaging with a brake means 57 described later.

  As shown in FIG. 39, the brake means 57 according to the second example is disposed so as to face the side surface of the wire reel 13 (surface perpendicular to the rotation axis of the wire reel 13). The brake means 57 is fixed so as to be swingable with respect to the binding machine main body 11. A long hole 57a is provided on one side across the swing shaft 57b, and a friction surface 57c is provided on the other side. Is provided.

  The long hole 57 a is for engaging with the advance / retreat fixing portion 31. Specifically, the long hole 57 a is engaged with a pin-shaped engagement portion 31 a provided in the advance / retreat fixing portion 31. The long hole 57 a is formed slightly oblique to the longitudinal direction of the brake means 57. For this reason, the inclination of the brake means 57 changes with the position where the engaging part 31a engages with the long hole 57a. By providing the long hole 57a obliquely in this way, the engaging part 31a moves along the long hole 57a and the brake means 57 swings when the advance / retreat fixing part 31 moves forward or backward. .

The friction surface 57c is disposed so as to face the side surface of the wire reel 13, and the friction surface 57c is pressed against the side surface of the wire reel 13 when the brake means 57 swings in the direction of the wire reel 13. Yes.
The brake means 57 is configured to swing in conjunction with an operation in which the advance / retreat fixing portion 31 moves forward or backward.

  Specifically, when the advance / retreat fixing portion 31 moves forward, the engaging portion 31a slides along the long hole 57a. As a result, the inclination of the brake means 57 changes, and the brake means 57 swings about the swing shaft 57b. When the brake means 57 swings in this way, the friction surface 57c at the tip is pressed against the side surface of the wire reel 13 so that the brake is applied.

Further, when the advance / retreat fixing portion 31 moves backward, the engaging portion 31a slides in the reverse direction along the long hole 57a. As a result, the inclination of the brake means 57 changes, and the brake means 57 swings in the reverse direction about the swing shaft 57b. When the brake means 57 swings in the reverse direction as described above, the friction surface 57c at the tip is separated from the side surface of the wire reel 13, so that the brake is released.
Even with such a configuration, the same effects as those of the friction brake example 1 can be obtained.

(Friction brake example 3)
A friction brake example 3 will be described. The feature of Example 3 is that a friction brake different from the above-described structure is provided.

  As shown in FIG. 40, the brake mechanism 30 according to the third example includes an advance / retreat fixing portion 31 and a brake unit 58. In the third example, the advance / retreat fixing portion 31 connects the advance / retreat cylinder portion 24 and the brake means 58.

  The advance / retreat fixing portion 31 is a transmission member for transmitting the power of the torsion motor 21 as a power source to the brake means 58. The advance / retreat fixing portion 31 is fixed to the advance / retreat cylinder portion 24 of the torsion mechanism 20, and moves forward or backward in conjunction with the advance / retreat operation of the advance / retreat cylinder portion 24. In other words, the advance / retreat fixing portion 31 moves forward integrally with the advance / retreat cylinder portion 24 when the torsion motor 21 rotates forward, and rearward integrally with the advance / retreat cylinder portion 24 when the torsion motor 21 reverses. To move to. The advancing / retracting fixing portion 31 is formed with a projecting pin-shaped engaging portion 31 a for engaging with a brake means 58 described later.

  As shown in FIG. 40, the brake means 58 according to the third example is disposed so as to sandwich the flange 13a of the wire reel 13. The brake means 58 includes a pair of link members 58a and a pair of clamping members 58c.

  One end of the pair of link members 58a is rotatably fixed to the advance / retreat fixing portion 31, and the other end is fixed to an end portion of the corresponding holding member 58c. Specifically, one end portion of the link member 58a is rotatably fixed to a pin-shaped engagement portion 31a provided in the advance / retreat fixing portion 31. The other end of the link member 58a is rotatably fixed to the end of the clamping member 58c by a connecting shaft 58b.

The pair of clamping members 58c is fixed to the binding machine body 11 so as to be rotatable about a fixed shaft 58d. One end of the clamping member 58c sandwiching the fixed shaft 58d is connected to the link member 58a by a connecting shaft 58b, and a friction surface 58e is provided at the other end.
The pair of clamping members 58c are configured to rotate in conjunction with the operation in which the advance / retreat fixing portion 31 moves forward or backward.

  Specifically, when the advance / retreat fixing portion 31 moves forward, the pair of link members 58a are pulled in the closing direction by being pulled by the engaging portion 31a, and the pair of link members 58a are rotated in the closing direction, thereby connecting shafts. When pulled by 58b, the pair of clamping members 58c also rotate in the closing direction. Thus, when the pair of clamping members 58c rotate in the closing direction, the flange 13a of the wire reel 13 is clamped by the friction surface 58e at the tip so that the brake is applied.

When the advancing / retracting fixing portion 31 is retracted, the pair of link members 58a are pushed into the engaging portion 31a to rotate in the opening direction, and the pair of link members 58a are pushed into the connecting shaft 58b by rotating in the opening direction. Accordingly, the pair of clamping members 58c also rotate in the opening direction. Thus, when the pair of clamping members 58c rotate in the opening direction, the clamping of the flange 13a of the wire reel 13 is released, so that the brake is released.
Even with such a configuration, the same effects as those of the friction brake example 1 can be obtained.

(Friction brake example 4)
A friction brake example 4 will be described. The feature of Example 4 is that a friction brake different from the above-described structure is provided.

  As shown in FIGS. 41 and 42, the brake mechanism 30 according to the fourth example includes an advance / retreat fixing portion 31, a movable plate 59, a rotating plate 60, a guide pin 62, a brake means 61, and a sliding guide member. 64. In Example 4, the advance / retreat fixing portion 31, the movable plate 59, and the rotating plate 60 connect the advance / retreat cylinder portion 24 and the brake means 61.

  The advance / retreat fixing portion 31 is a transmission member for transmitting the power of the torsion motor 21 as a power source to the brake means 61. The advance / retreat fixing portion 31 is fixed to the advance / retreat cylinder portion 24 of the torsion mechanism 20, and moves forward or backward in conjunction with the advance / retreat operation of the advance / retreat cylinder portion 24. In other words, the advance / retreat fixing portion 31 moves forward integrally with the advance / retreat cylinder portion 24 when the torsion motor 21 rotates forward, and rearward integrally with the advance / retreat cylinder portion 24 when the torsion motor 21 reverses. To move to. The advancing / retracting fixing portion 31 is formed with a projecting pin-shaped engaging portion 31 a for engaging with a movable plate 59 described later.

  One end portion of the movable plate 59 is fixed to the advance / retreat fixing portion 31 so as to freely rotate, and the other end portion is fixed to the rotation plate 60. Specifically, one end of the movable plate 59 is rotatably fixed to a pin-shaped engaging portion 31 a provided in the advance / retreat fixing portion 31. The other end of the movable plate 59 is fixed to the rotary plate 60 by a connecting pin 59a.

  The rotation plate 60 is a plate that is rotatably mounted on the same axis as the rotation axis of the wire reel 13, and as shown in FIG. 43 (a), a pin connection hole 60a provided at an eccentric position and a curved length. A pair of guide holes 60b formed as holes are provided. The pin connection hole 60 a is a hole for allowing the connection pin 59 a to pass through and connecting to the movable plate 59. The guide hole 60b is for guiding the movement of the guide pin 62 through a guide pin 62 described later. The guide hole 60b is formed so as to move away from the center in the predetermined rotation direction (clockwise direction in FIG. 43A).

  The guide pin 62 is a pin that is slidably engaged with the guide hole 60b. Two guide pins 62 are provided corresponding to each of the pair of guide holes 60b. Brake means 61 are fixed to the tips of the two guide pins 62, respectively.

  The brake means 61 is disposed inside the wire reel 13 and moves outward to brake the wire reel 13. The brake means 61 is a block-shaped member as shown in FIG. As shown in FIG. 41 (c), the brake means 61 is disposed so as to face the inner peripheral surface of the engagement hole 13 d provided in the vicinity of the rotation axis of the wire reel 13. The surface facing the inner peripheral surface of the engagement hole 13d of the wire reel 13 forms a friction surface 58e so that the wire reel 13 can be engaged and braked.

The sliding guide member 64 is a member that guides the sliding of the brake means 61. By providing this sliding guide member 64, the brake means 61 is regulated so as to be movable only in the radial direction. The sliding guide member 64 is fixed to the body housing 63 of the binding machine body 11.
The brake means 61 described above moves in the outer peripheral direction or the inner peripheral direction in conjunction with the operation in which the advance / retreat fixing portion 31 moves forward or backward.

  Specifically, when the advance / retreat fixing portion 31 moves forward, the movable plate 59 is also moved in the forward direction by being pulled by the engagement portion 31a as shown in FIG. When the movable plate 59 moves in the forward direction, the rotating plate 60 rotates as shown in FIG. When the rotating plate 60 rotates, the guide pin 62 moves along the guide hole 60b. At this time, the guide pin 62 moves in the outer circumferential direction because the guide hole 60b is formed to move away from the center as it goes in the rotation direction. When the guide pin 62 moves in the outer circumferential direction, the brake means 61 also moves integrally in the outer circumferential direction, so that the friction surface 61a of the brake means 61 is engaged with the engagement hole 13d of the wire reel 13 as shown in FIG. It is pressed against the inner peripheral surface of the door and the brake is applied.

When the advance / retreat fixing portion 31 moves backward, the rotary plate 60 rotates in the opposite direction to the previous one, and the guide pin 62 moves in the inner circumferential direction. When the guide pin 62 moves in the inner circumferential direction, the brake means 61 also moves integrally in the inner circumferential direction, so that the friction surface 61a of the brake means 61 engages with the wire reel 13 as shown in FIG. The brake is released away from the inner peripheral surface of the hole 13d.
Even with such a configuration, the same effects as those of the friction brake example 1 can be obtained.

DESCRIPTION OF SYMBOLS 10 Rebar binding machine 11 Binding machine main body 12 Curl formation part 13 Wire reel 13a Flange 13b Engagement part 13c Protrusion part 13d Engagement hole 20 Torsion mechanism 21 Torsion motor (power source)
22 gear 23 screw shaft part 24 advance / retreat cylinder part 25 hook for twist 30 brake mechanism 31 advance / retreat fixing part (transmission member)
31a engaging portion 32 linear motion member 32a receiving portion 32b guide groove 32c connecting pin 33 guide pin 34 rocking member 34a engaging hole 35 rotating shaft 36 brake means 36a claw portion 36b pressed portion 36c base portion 36d intermediate portion 36e tip portion 36f 1st oscillating node 36g 2nd oscillating node 36h 1st urging member 36i 2nd urging member 36j elastic deformation part 37 engagement urging means 38 release urging means 39 spring receiving part 40 first link member 40a receiving part 40b Rotating fulcrum 40c Joint portion 41 Second link member 41a Connection pin 42 Switching member 42a Pressing portion 43 Support shaft 44 Buffer spring 50 Clutch mechanism 51 Shaft 52 Clutch plate 52a Engaging recess 53 Clutch gear 53a Guide hole 54 Ball 55 Clutch spring 56 Friction surface 57 Brake means 57a Slot 57b Rocking Shaft 57c Friction surface 58 Brake means 58a Link member 58b Connection shaft 58c Holding member 58d Fixed shaft 58e Friction surface 59 Movable plate 59a Connection pin 60 Rotation plate 60a Pin connection hole 60b Guide hole 61 Brake means 61a Friction surface 62 Guide pin 63 Body housing 64 Sliding guide member W Wire E Foreign object

Claims (7)

A rebar binding machine that sends out a binding wire and wraps it around the rebar to bind it,
A wire reel that is rotatably supported by the binding machine body;
Brake means for stopping the rotation of the wire reel;
A power source for operating the brake means;
A transmission member for transmitting the power of the power source to the brake means;
With
A reinforcing bar binding machine, wherein a buffer mechanism is provided on a power transmission path for transmitting the power of the brake means or the power source to the brake means.   The power source drives the transmission member in the forward direction when operating the brake means in the stop direction of the wire reel, and retracts the transmission member when operating the brake means in the stop release direction of the wire reel. The reinforcing bar binding machine according to claim 1, wherein the reinforcing bar binding machine is driven in a direction.   The reinforcing bar binding machine according to claim 1 or 2, wherein rotation of the wire reel is suppressed by engagement with the brake means. The buffer mechanism includes an engagement urging unit that urges the brake unit in a direction to engage with the wire reel,
The reinforcing bar according to claim 3, wherein the transmission member moves the brake means in a direction in which the engagement with the wire reel is released against the urging force of the engagement urging means. Binding machine. The buffer mechanism includes a release biasing unit that biases the brake unit in a direction in which the engagement with the wire reel is released,
5. The reinforcing bar binding machine according to claim 3, wherein the transmission member moves the brake means in a direction to engage with the wire reel against an urging force of the release urging means.   The reinforcing bar binding machine according to any one of claims 1 to 5, wherein the buffer mechanism is configured by making the brake means elastically deformable.   As the power source, a torsion motor that drives a torsion hook for twisting and binding the binding wire is used, and the transmission member moves forward or backward in conjunction with the advancement or retraction of the torsion hook. The reinforcing bar binding machine according to any one of claims 1 to 6, wherein:

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