KR100431690B1 - Apparatus for binding wire - Google Patents

Abstract

The present invention provides a wire binding device for twisting at least one pair of wires in a certain section, comprising: an apparatus main body; A rotating shaft rotatably coupled to the apparatus body; A gripping portion provided at an end of the rotating shaft to grip at least a portion of each of the wires; Rotation driving means provided on the apparatus main body to rotate the rotation shaft to bind the wire by the gripping portion; It characterized in that it comprises a rotation variable stage for varying the rotation direction of the rotary shaft. Thereby, a wire binding device is provided which makes it possible to shorten the time required while facilitating the binding operation and the release operation of the wire.

Description

Wire binding device {APPARATUS FOR BINDING WIRE}

The present invention relates to a wire binding device, and more particularly, to a wire binding device that can be used when a pair of wires, electric wires, wires, and the like are integrally knotted.

A wire binding device is a kind of device for convenient use when a pair of wires, wires, and wires are integrally knotted. The wire binding device can be variously applied according to the type and use of the wire used. In the following description, a wire binding device is applied to a pair of orthodontic wires that are integrally connected to the teeth during orthodontic treatment to correct the warping state of the teeth in some sections.

Normally during orthodontic treatment to treat malocclusion, a moving moving tooth (usually "front tooth") and a stationary tooth (mainly "molar tooth") for better chewing function in the molar area and better pronunciation and aesthetic function in the front tooth area. The proper force adjustment between the "" is very important.

For example, when correcting a coarse or crooked tooth, use a orthodontic device consisting of a bracket attached to the tooth and a orthodontic wire that connects it between teeth when removing the small molars and causing the incisor to move into this space. Done.

Due to this orthodontic device is applied to the front teeth moving toward the molars. However, the opposite reaction appears in the molar area, so that the molars that should not be moved are moved forward to occupy the space of the extracted tooth area, thereby preventing the incisor from moving as much as desired.

So-called orthodontics use a dental orthodontic device that is removable from the teeth to reduce this reaction and provide space for the mobile tooth to move sufficiently. However, in the case of adults, it is difficult to obtain a surgical coordination of a removable orthodontic device for aesthetic reasons and cumbersome insertion.

Therefore, in the roots, a small screw called a mini implant is placed in the gum bone between the root of the tooth and the root, and the teeth to be corrected with the mini implant as the supporting shaft are connected with elastic material and orthodontic wire, and finally the wire is connected. Twist and fix the teeth.

However, in the related art, when the wire is twisted at almost the final stage of orthodontic treatment, the wire is tied by using a long, pointed tool such as a long nose, and the operator twists the wire while twisting the wire while binding the wrist. .

Therefore, not only the procedure for binding the wire is easy, but also fatigue is accumulated in the arm or wrist of the operator, so the reliability of the procedure may be lowered. In addition, when the number of wires to be bound is large, there is a drawback that the wire binding time is very long.

Accordingly, it is an object of the present invention to provide a wire binding device which can shorten the time required while facilitating the binding operation and the release operation of the wire.

1 is a perspective view of a wire binding device according to a first embodiment of the present invention,

2 is a schematic cross-sectional view of FIG.

3 to 5 is an operating state of the wire binding device according to the first embodiment,

6 (a) and 6 (b) are cross-sectional views of an operating state of a gripper region according to a second embodiment of the present invention;

7 (a) and 7 (b) are cross-sectional views of an operating state of a gripper region according to a third embodiment of the present invention;

8 (a) and 8 (b) are cross-sectional views of an operating state of a gripper region according to a fourth embodiment of the present invention;

9 is a cross-sectional view of a gripper region according to a fifth embodiment of the present invention.

* Explanation of symbols for the main parts of the drawings

10: device body 20: rotation axis

30: holding part 40: congratulation

50: rotation means 51: drive bevel gear

52: driven bevel gear 53: drive unit

54: push button portion 56: electric portion

70: rotation variable stage 71: reverse bevel gear

In accordance with the present invention, a wire binding device for twisting at least a pair of wires in some sections, the device body; A rotating shaft rotatably coupled to the apparatus body; A gripping portion provided at an end of the rotating shaft to grip at least a portion of each of the wires; Rotation driving means provided on the apparatus main body to rotate the rotation shaft to bind the wire by the gripping portion; It is achieved by a wire binding device characterized in that it comprises a rotation variable stage for varying the rotation direction of the rotary shaft.

Here, the rotating means is configured to have a drive bevel gear provided at the end of the rotating shaft, a driven bevel gear to rotate the drive bevel gear by mutually inclined to the drive bevel gear, and a drive unit for driving the driven bevel gear. can do.

At this time, the driving unit is exposed to the outside of the device body is connected to the push button unit, the push button unit and the driven bevel gear integrally to convert the linear movement of the push button unit to the rotational movement of the driven bevel gear It includes an electric drive.

By providing an elastic spring coupled to the push button part and elastically urging in a direction opposite to the pressing direction of the push button part, the push button part can be returned to its original position.

On the other hand, the rotating variable stage is formed with the drive bevel gear and the teeth opposite to each other, the reverse bevel gear is provided to be spaced apart from the drive bevel gear by a predetermined distance on the rotating shaft; One end is coupled to the rotating shaft and the other end is exposed to the outside through a through hole formed in the apparatus body, and the driving bevel gear and the reverse bevel gear with respect to the driven bevel gear by moving the rotary shaft relative to the axis It may be configured to include an actuating lever for gear engagement.

On the rear surface of the apparatus body, a rotating shaft support protrusion for receiving and supporting the rotating shaft protrudes.

The celebration housing which is integrally wrapped with the rotary shaft and has a passage hole for passing the gripping portion at the front end, and interposed between the celebration housing and the apparatus main body in a direction in which the celebration housing is spaced apart from the apparatus main body. It is advantageous to provide a spring member for elastic bias.

Meanwhile, the gripping portion may be provided as a pair of gripping portions for gripping the wire. At this time, the mutually engaging teeth are formed on the mutual contact surfaces of the respective gripping portions, which is more effective in increasing the gripping strength of the wire. And, it may further include a spring which is interposed between the pair of gripping portions to separate each of the gripping portions.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings, in which each case according to the present invention is a case where the orthodontic wire is knotted with each other in some sections.

1 is a perspective view of a wire binding device according to the present invention, Figure 2 is a cross-sectional view of FIG. As shown in these figures, the wire binding device according to the present invention has a device body 10 and a gripping portion 30 to partially grip at least a portion of each wire (w) to rotate on the device body 10 Rotating shaft 20 that is connected to the possible, and the rotating means 50 provided on the device body 10 to rotate the grip portion 30 in at least one direction with respect to the axis of the rotating shaft 20.

Device body 10 is advantageously manufactured to have a size and weight enough to be gripped by the operator with one hand. The apparatus body 10 has a head portion 10a to which the rotary shaft 20 is coupled according to its position, and a grip portion 10b for holding by the operator. Although not shown, the gripping portion 10b may be provided with a gripping groove corresponding to the finger node to facilitate gripping, or may be attached with a separate anti-slip pad.

The rotating shaft 20 has an elongate rod shape, and a gripping portion 30 for holding the wire w is provided at the tip thereof. The gripping portion 30 takes the form of an elongated wire and has a partial ring shape with one end open (see enlarged "A" in FIG. 2). The rotation shaft 20 is disposed such that some areas where the gripping portion 30 is provided are exposed to the outside from the head portion 10a of the apparatus main body 10 and the remaining regions are disposed within the head portion 10a according to the position thereof. . Hereinafter, for convenience of description, the rotating shaft 20 is divided into an exposed area 20a and an insertion area 20b.

A boss portion 13 for supporting the rotating shaft 20 is provided on the side of the head portion 10a, and a rotating shaft support protrusion 14 is formed on the rear surface of the head portion 10a. Thus, the exposed area 20a of the rotating shaft 20 may be supported by the boss portion 13 and the insertion area 20b may be rotatably supported by the rotating shaft support protrusion 14.

On the outside of the exposed area 20a of the rotating shaft 20, a celebratory housing 40 for integrally wrapping the rotating shaft 20 is provided. The through hole 41 is formed at the tip of the celebratory housing 40 adjacent to the gripping portion 30 so that a portion of the gripping portion 30 having a wire shape passes through and is exposed to the outside. In addition, the position of the celebratory housing 40 is moved in the longitudinal direction of the rotation shaft 20 at a position spaced apart from the passage hole 41 so that the grip portion 30 may be completely exposed through the passage hole 41. A plate-shaped pressing plate 42 is provided. A spring member 44 is disposed between the boss portion 13 and the pressing plate 42 so as to surround the rotation shaft 20 in a ring shape, and is elastically biased between the head portion 10a and the pressing plate 42.

Thus, when the operator pulls the pressing plate 42 toward the head portion 10a, the spring member 44 is compressed, and the celebratory housing 40 moves a predetermined distance toward the head portion 10a, thereby interlocking with the annular shape. The gripping portion 30 is completely exposed to the outside through the through hole 41 of the celebratory housing 40. At this time, the operator inserts the wire w to be bound into the gripping portion 30 and then releases the force applied to the pressing plate 42. Then, as the spring member 44 elastically expands, the housing 40 moves forward and the gripping portion 30 is partially inserted into the through hole 15 of the housing 40 again. Therefore, the wire w sandwiched in the gripping portion 30 is supported by the pointed tip of the celebratory housing 40 so as not to be arbitrarily released from the gripping portion 30.

As described later in detail on the rotating shaft 20, one end is coupled to the rotating shaft 20 and the other end is provided with an operating lever 73 disposed to be exposed to the outside through the through hole 15 formed on the upper surface of the head (10a) Are combined. The operation lever 73 adjusts the rotation direction of the rotation shaft 20 while linearly moving the rotation shaft 20 along the axial direction of the rotation shaft 20.

The rotating means 50 is inclined to the driving bevel gear 51 and the driving bevel gear 51 provided in the insertion region 20b of the rotating shaft 20 accommodated in the head portion 10a and the driving bevel gear 51. And a driven bevel gear 52 for rotating), and a driving unit 53 for driving the driven bevel gear 52.

The driven bevel gear 52 is larger in size than the drive and reverse bevel gears 51 and 71 and arranged along the horizontal direction for gear engagement with the reverse bevel gear 71 to be described later. In addition, the driven bevel gear 52 couples the bracket engaging portion 58 to the dummy member 57 formed at the mutual boundary area between the head portion 10a and the handle portion 10b, and uses the rod 59 to mount the bracket. It is rotatably supported relative to the engaging portion 58. Here, it goes without saying that the bevel gears 51, 52, and 71 of the bevel gears 51, 52, and 71 including the driven bevel gears 52 may be appropriately changed as necessary.

The driving part 53 is integrally connected to the push button part 54 and the push button part 54 and the driven bevel gear 52 which are exposed to the outside of the grip handle 10b of the device body 10, and is pressed. The transmission part 56 which converts the linear motion of the button part 54 into the rotational motion of the driven bevel gear 52 is provided. Therefore, when the operator presses the push button portion 54 linearly toward the apparatus body 10 side, the driven bevel gear (by the driven portion 56 eccentrically arranged to one side below the driven bevel gear 52) 52 may rotate about rod 59.

At this time, since the driving bevel gears 51 are inclined to each other in the driven bevel gears 52, the driving bevel gears 51 rotate by the rotation of the driven bevel gears 52, and the driving bevel gears 51 are rotated. The combined rotating shaft 20 may also rotate along the axial direction. Hereinafter, for convenience of description, it is assumed that the direction in which the rotating shaft 20 rotates by the driving bevel gear 51 is the forward direction, and the direction in which the rotating shaft 20 is rotated by the reverse bevel gear 71 to be described later is the reverse direction. Explain.

An inner side of the handle portion 10b is provided with an elastic spring 60 parallel to the pressing direction of the push button portion 54. One end of the elastic spring 60 is fixed by a spring coupling portion 62 formed on the inner surface of the handle portion 10b and the other end thereof is coupled to the end portion of the push button portion 54. Thus, the push button portion 54 pressed to rotate the rotation shaft 20 in the forward direction may be returned to its original position by the elastic spring 60.

On the other hand, in the present invention, the rotation direction of the rotation shaft 20 can be rotated in the reverse direction instead of the forward direction. To this end, the rotation variable stage 70 is further provided. The rotary variable stage 70 is formed so that the teeth of the driving bevel gear 51 and the tooth opposite to each other is provided to be spaced apart from the driving bevel gear 51 by a predetermined distance in the insertion region 20b of the rotating shaft 20, and driven bevel gear 52 And a reverse bevel gear 71 that is tooth-coupled to () and the above-described operating lever (73).

In the present embodiment, the reverse bevel gear 71 is fixed to the rotation shaft 20 so that its position is opposite to that of the driving bevel gear 51. Thus, the operator moves the actuating lever 73 in one direction (see the arrow "F" direction in FIG. 5) so that the driving bevel gear 51 is disengaged from the driven bevel gear 52 and the reverse bevel gear to the driven bevel gear 52. After the 71 is engaged, when the pushbutton 54 is pressed, the driven bevel gear 52 is rotated by the transmission 56, and the reverse bevel gear 71 engaged with the driven bevel gear 52 is engaged. Rotates the rotating shaft 20 while rotating. At this time, the rotation direction of the rotation shaft 20 is in the opposite direction to the direction by the above-described driving bevel gear 51.

By such a configuration, a procedure of twisting and binding the wire w using the orthodontic binding device according to the first embodiment of the present invention will be described with reference to FIGS. 3 to 5 as follows.

First, the operator pulls the pressing plate 42 formed on the celebratory housing 40 toward the head portion 10a by using an index finger or a middle finger while holding the grip portion 10b for holding (the arrow “D” direction in FIG. 3). Reference). Then, as the spring member 44 is compressed, the celebratory housing 40 moves a predetermined distance toward the head portion 10a, and the grip portion 30 having a ring shape in connection with the circulating housing 40 passes through the celebratory housing 40 ( 41) fully exposed to the outside.

At this time, the practitioner releases the force applied to the pressing plate 42 after properly inserting the wire w to be bound to the gripping portion 30 (see enlarged "B" in FIG. 3). Then, as the spring member 44 elastically expands, the housing 40 moves forward and the gripping portion 30 is partially inserted into the through hole 15 of the housing 40 again. Therefore, the wire w sandwiched in the gripping portion 30 is supported by the tip of the celebration housing 40 so as not to be released from the gripping portion 30 arbitrarily.

In this state, the operator presses the push button part 54 toward the apparatus main body 10 side (see arrow "E" direction in FIG. 4). Then, the linear movement of the push button portion 54 is directed to the driven bevel gear 52 through the transmission 56, and by their mechanism, the driven bevel gear 52 can rotate about the axis of the rod 59. Can be.

At this time, since the driving bevel gears 51 are mutually inclined to the driven bevel gears 52, the driving bevel gears 51 can rotate by the rotation of the driven bevel gears 52, and the driving bevel gears 51 Rotating shaft 20 coupled to) may also rotate in the forward direction along the axial direction. Thus, the wire w sandwiched in the gripping portion 30 can be knotted (see enlarged " C " in FIG. 4). Here, if the dimensions of each bevel gear (51, 52, 71) and the movement distance of the push button portion 54 is properly adjusted, the rotation ratio of the rotation shaft 20 to the single press of the push button portion 54 is properly adjusted. Can be calculated Here, in the drawing, when the push button portion 54 is returned by the elastic spring 60, the driven bevel gear 52 is shown to rotate in the reverse direction, but this is only shown for convenience of description, When the push button portion 54 returns, the driven bevel gear 52 should not rotate in the reverse direction. Therefore, a separate means is required so that the return movement of the push button portion 54 does not interfere with the driven bevel gear 52. To this end, it is more effective to provide idle driving means (not shown) in the driven bevel gear 52 and the transmission unit 56 so as not to interfere with each other.

On the other hand, when it is necessary to rotate the rotating shaft 20 in the reverse direction, that is, to untie the wire w, the operator advances the operating lever 73 forward (arrow “F” in FIG. 4). Direction). Then, the driving bevel gear 51 is disengaged from the driven bevel gear 52, and the reverse bevel gear 71 disposed behind is toothed to the driven bevel gear 52. In this state, too, when the operator presses the push button portion 54 toward the apparatus main body 10 side (see arrow "G" direction in FIG. 4), the driven bevel gear 52 is driven by the transmission portion 56. The rotating bevel gear 71 receives the rotational force to rotate the rotating shaft 20 in the reverse direction.

As such, when the operation of binding the wire w is completed, the operator pulls the pressing plate 42 formed on the celebration housing 40 toward the head portion 10a again, and the grip portion 30 to which the wire w is bound is attached. By releasing the wire w from the gripping portion 30 in a state in which it is almost exposed to the outside through the passage hole 41 of the conical housing 40, the binding work of the wire w is simply finished.

As described above, in the present invention, not only the wire w and the like can be easily bound and released, but also the time required can be shortened. In addition, since the procedure of binding the wire (w) is easy, fatigue does not accumulate in the arm or wrist of the operator, thereby increasing the reliability of the procedure.

In the above-described embodiment, the grip portion 30 is shaped like an annular shape (see enlarged " A " in FIG. 2) with one end open. However, the gripping portion 30 and the congratulation housing 40 may be configured as in the following embodiments, of course.

In Fig. 6 showing the second embodiment, the gripping portion 30a provided at the end of the rotating shaft 20a is provided as a pair of gripping portions 30a 'and 30a "and provided in the celebratory housing 40a. The spring 80a is elastically biased in a direction in which the pair of gripping portions 30a ', 30a "are spaced apart from each other.

Thus, similarly to the description in the first embodiment, when the celebratory housing 40a is moved in the direction of the arrow shown in (a), the holding part 30a housed in the celebratory housing 40a is the celebratory housing 40a. The both ends are opened to each other by the spring (80a) while being exposed from). At this time, after arranging the wire w to be bound between the pair of gripping portions 30a 'and 30a', the pair of moving housings 40a are moved in the direction of the arrow shown in (b). The gripping portion of the glove portion is accommodated into the celebratory housing 40a in a state of holding the wire w. At this time, the gripping portion 30a is rotated by using a predetermined rotating means (not shown). The bite wire w can be twisted to bind.

In addition to the configuration of Fig. 6, as shown in Fig. 7 shown in the third embodiment, the shape of the pair of gripping portions 30b 'and 30b " provided at the end of the rotating shaft 70b may be toothed. It is possible to further increase the strength of gripping the wire w. The operation description of the third embodiment is the same as that of the above-described second embodiment, and thus the description is omitted.

FIG. 8 shows a fourth embodiment, which is almost similar to the third embodiment, except that one gripping portion 30c "of the gripping portion 30c is fixed, and the gripping portion 30c 'of the other side is fixed. The gripping portion 30c "can be rotated. This also makes it possible to further increase the strength of gripping the wire w than in the second embodiment. The description of the operation of the fourth embodiment is the same as that of the second and third embodiments described above, and thus the description is omitted.

On the other hand, after holding the wire (w), in the process of binding the wire (w) while rotating, if the sharp portion of the tip of the wire (w) touches the gum or the wall surface of the mouth may be hurt. Thus, as shown in FIG. 9 showing the fifth embodiment, a predetermined wire winding means 90 is provided outside the celebration housing 40d and the tip of the wire w held by the gripping portion 30d is removed. After winding the wire winding means 90 and twisting the wire w together while rotating the rotary shaft 20d, it is possible to suppress the wound of the wall surface of the gum or mouth due to the wire w. And, the wire winding means may be in the form of a protrusion, as shown in Figure 9, one end is rotatably coupled to the outside of the celebration housing to keep the front end of the wire (w) in close contact with the outside of the celebration housing Of course, it can also be applied as a cover structure (not shown) to shield it.

Although the above-described embodiments disclose a celebratory housing covering the rotating shaft, the axial housing may be provided without providing the celebratory housing.

That is, as shown in FIG. 10, the holding part 40e has a pair of holding end parts 31e and 32e holding the wire w and a pair of holding end parts 31e and 32e. Handle portions 41e and 42e should be provided. Accordingly, the wires w are disposed between the respective grip end portions 31e and 32e in a state where the pair of grip portions 41e and 42e are approached to each other and the pair of grip end portions 31e and 32e are spaced apart from each other. When the force applied to the pair of handle portions 41e and 42e is released, it is desirable to allow the pair of holding ends 31e and 32e to grip the wire w while mutually approaching by the repulsive force of the spring 80e. Do.

In addition to the above-described embodiment, it is also possible to use a motor rotatable in the forward and reverse directions and to connect the rotary shaft to the motor to rotate the rotary shaft in the forward and reverse directions through an on / off switch.

As described above, according to the present invention, there is provided a wire binding device that can shorten the time required while facilitating the binding operation and the release operation of the wire.

Claims (11)

In the wire binding device for twisting at least one pair of wires in some section, An apparatus body; A rotating shaft rotatably coupled to the apparatus body; A gripping portion provided at an end of the rotating shaft to grip at least a portion of each of the wires; Rotation driving means provided on the apparatus main body to rotate the rotation shaft to bind the wire by the gripping portion; Wire binding device characterized in that it comprises a rotation variable stage for varying the rotation direction of the rotary shaft. The method of claim 1, The rotating means includes a driving bevel gear provided at an end of the rotating shaft, a driven bevel gear inclined to the driving bevel gear to rotate the driving bevel gear, and a driving unit for driving the driven bevel gear. Wire binding device. The method of claim 2, The driving unit is exposed to the outside of the apparatus body and includes a push button unit, the transmission unit integrally connected to the push button unit and the driven bevel gear to convert the linear movement of the push button unit to the rotational movement of the driven bevel gear. Wire binding device, characterized in that. The method of claim 3, And an elastic spring coupled to the push button part to elastically bias in a direction opposite to the pressing direction of the push button part. delete The method of claim 1, The rotating variable stage is formed with the drive bevel gear and the teeth opposite to each other, the reverse bevel gear is provided to be spaced apart from the drive bevel gear by a predetermined distance on the rotating shaft; One end is coupled to the rotary shaft and the other end is exposed to the outside through the through hole formed in the device body and to engage the one of the drive and the reverse bevel gear relative to the driven bevel gear by moving the rotary shaft relative to the axis. Wire binding device comprising an operating lever. The method of claim 6, And a rotation shaft support protrusion protruding from the rear surface of the apparatus body to receive and support the rotation shaft. The method of claim 1, The celebration housing which is integrally wrapped with the rotary shaft and has a passage hole for passing the gripping portion at the front end, and interposed between the celebration housing and the apparatus main body in a direction in which the celebration housing is spaced apart from the apparatus main body. Wire binding device further comprises a spring member for elasticity. The method of claim 1, The gripping portion is a wire binding device, characterized in that provided with a pair of gripping portions for gripping the wire. The method of claim 9, Wire binding device, characterized in that the teeth that can be engaged with each other is formed on the mutual contact surface of each holding portion. The method of claim 9, And a spring interposed between the pair of gripping portions to separate the gripping portions from each other.