KR20160055854A - Bit connector and screw tightening device - Google Patents

Abstract

The bit connector 30 is provided with a shaft in which an insertion hole 301 for inserting a bit along the central axis is formed and at least one hole 304 extending from the outer circumferential surface to the insertion hole is formed, (34, 35) disposed in the at least one hole such that a part thereof is positioned in the insertion port and movable in a direction intersecting with the center axis in a state where the inserting hole is not inserted, And a stop ring 38 which pushes in the direction of the central axis.

Description

TECHNICAL FIELD [0001] The present invention relates to a bit connector and a screw tightening device,

The present invention relates to a technique for mounting a bit on a rotary shaft.

As a configuration for mounting a bit on a shaft, for example, there is a configuration disclosed in Patent Document 1. In the shaft disclosed in Patent Document 1, a hole is provided in a cylindrical portion, and the ball is accommodated in the hole. A part of the ball housed in the hole is pushed by a chuck provided on the outer peripheral surface of the shaft to protrude into the hollow portion of the shaft. In the bit, a circumferential groove is provided at a portion to be inserted into the hollow portion of the shaft. When the ball of the sleeve engages a portion of the groove of the bit, the bit does not move in the axial direction, and when the sleeve rotates, the bit rotates as the sleeve rotates.

Japanese Laid-Open Patent Publication No. 04-365563

In the structure disclosed in Patent Document 1, when the bit is mounted on the shaft, the chuck is moved to move the ball to the gap between the shaft and the chuck, then the bit is inserted into the shaft and the chuck is moved again, . Further, when the bit is detached from the shaft, the ball is removed from the groove of the bit by moving the chuck to move the ball to the gap between the shaft and the chuck. When the ball is removed from the groove of the bit, the bit becomes movable in the axial direction and the bit can be removed from the shaft.

As described above, in the configuration disclosed in Patent Document 1, when the bit is mounted on the shaft or when the bit is detached from the shaft, it is necessary to move the chuck, and it takes time to replace the bit.

The present invention aims at facilitating the exchange of bits.

According to one aspect of the present invention, there is provided a shaft comprising: a shaft formed with an insertion port for inserting a bit along a central axis, at least one hole extending from an outer circumferential surface to the insertion port; A fastener disposed in the at least one hole such that a portion thereof is positioned in the insertion port and movable in a direction crossing the central axis; and a detent ring having elasticity and pressing the fixture in the direction of the central axis and a retaining ring.

In a preferred form, the at least one hole includes two holes facing each other, and one of the holes is disposed in each hole.

In a preferred form, two grooves are formed along the circumferential direction on the outer circumferential surface, an auxiliary stop ring is fitted into each groove, and the stop ring is fixed to the shaft by two auxiliary stop rings.

In a preferred form, the fixture is spherical.

According to another aspect of the present invention, there is provided a shaft, comprising: a shaft having an insertion port for inserting a bit along a central axis, the shaft having at least one hole extending from an outer circumferential surface to the insertion port; A bit connection port having elasticity and a detent ring for pressing the fixture in the direction of the central axis, and a recess formed in the outer circumference surface, the recess being fixed to the shaft by being caught by the fixture And a driving unit for rotating the center shaft.

In a preferred form, the screw tightening device further comprises: a cover for covering the bit; and a case having a cover for fixing the cover, a passage passage accommodating the drive portion therein and communicating with the gap, And sucked out of the case.

According to the present invention, it is possible to facilitate the exchange of bits as compared with a configuration in which bits are exchanged by moving the chuck.

1 is a view showing the external appearance of a screw fastening apparatus 1 according to an embodiment of the present invention.
Fig. 2 is a sectional view of the screw fastening device 1. Fig.
Figure 3 is a front view and a right side view of the bit 10.
Fig. 4 is a view showing an outer appearance of the motor 30 and an end of the shaft 31. Fig.
Fig. 5 is a view for explaining the operation when the bit 10 is mounted on the screw fastening device 1. Fig.
6 is a view showing an appearance of a pin according to a modification.
Fig. 7 is a view showing a cross section of the insertion portion 103 according to a modification.

[Embodiment Mode]

1 is a view showing the external appearance of a screw fastening apparatus 1 according to an embodiment of the present invention. The screw fastening device 1 is a suction type screw fastening device that sucks air around the tip of a bit into the device and sucks the screw at the tip of the bit. Hereinafter, for convenience of explanation, the bit side of the screw fastening device 1 is referred to as the front side, and the opposite side of the bit side is referred to as the back side.

Fig. 2 is a sectional view of the screw fastening device 1. Fig. On the rear side of the main body case 14, a rear cover 15 for blocking the rear side of the main body case 14 is mounted. A part of the main body case 14 is provided with a passage 141 penetrating from the front side to the rear side of the main body case 14 and having a length through which air flows.

The rear cover 15 is provided with a connector 20 to which a control cable is connected. When a signal for controlling the motor is supplied from the control cable to the connector 20, the motor 30 for rotating the bit 10 is driven, and the number of revolutions of the bit 10 or the torque of the screwing is controlled. The rear cover 15 is also provided with a hollow connector 21 to which a tube for sucking the air sucked from around the tip of the bit 10 from the screw tightening device 1 is attached.

The motor 30 is a motor for rotating the bit 10. The motor 30 is screwed to the motor mount 13 which closes the front side of the main body case 14 and is positioned inside the main body case 14 as shown in Fig. A part of the motor mount 13 is provided with a passage 131 passing through from the front side to the rear side so that air can pass therethrough.

The tubular connecting joint 16 is a joint for connecting the passage 141 and the passage 131. 2, the front side of the connecting joint 16 is housed inside the motor mount 13, and the rear side is housed inside the main body case 14. As shown in Fig.

The tubular O-ring holder 17 is a part for holding the O-ring 171 that prevents the air sucked from around the tip end of the bit 10 from flowing into the body case 14. [ The O-ring holder 17 is mounted on the front side of the motor mount 13. The bit 10 is supported by the O-ring holder 17 and the O-ring 171, and movement of the bit 10 in the radial direction is restricted.

The retainer 12 is a cover that covers the O-ring holder 17 and the bit 10, and is mounted on the motor mount 13 by screws. The inner diameter of the space in the retainer 12 is larger than the diameter of the bit 10 at any position and there is a clearance between the bit 10 and the retainer 12. When the retainer 12 is mounted on the motor mount 13, the space in the retainer 12 is connected to the passageway 131.

The first cover 11A and the second cover 11B are covers covering the front side of the center of the bit 10. The second cover 11B is mounted on the front side of the retainer 12 and the first cover 11A is mounted on the front side of the second cover 11B.

2, the flow of air sucked from around the tip of the bit 10 is indicated by an arrow. The air in the passage 141 leading to the connector 21 flows from the connector 21 to the tube since the air in the tube connected to the connector 21 is sucked by the pump connected to the tube. The passage 141 is connected to the passage 131 through the connecting joint 16 so that the air in the connecting joint 16 and the air in the passage 131 , And flows toward the passage (141).

Since the passage 131 is connected to the space in the holder 12, the air in the holder 12 flows toward the passage 131 when the air in the passage 131 flows backward. Since the O-ring 171 is in contact with the bit 10 in the O-ring holder 17, the air in front of the O-ring holder 17 is located behind the O-ring 171, 14).

Since the inner diameters of the first cover 11A and the second cover 11B are larger than the outer diameter of the bit 10, there is a gap between the first cover 11A and the bit 10, ) And the bit 10, as shown in Fig. Since the hollow portion of the second cover 11B is connected to the space in the retainer 12, if the air in the retainer 12 flows backward, the air in the gap between the bit 10 and the second cover 11B Air flows to the side of the retainer 12 and air in the gap between the bit 10 and the first cover 11A flows toward the second cover 11B side. When air in the gap between the bit 10 and the first cover 11A flows backward, the air around the tip of the bit 10 is sucked into the gap between the bit 10 and the first cover 11A. When the tip of the bit 10 approaches the head of the screw, the screw is attracted to the tip of the bit 10 as the air around the tip of the bit 10 is sucked into the first cover 11A.

Next, a configuration for mounting the bit 10 to the screw fastening apparatus 1 will be described. 3 is a front view and a right side view of the bit 10. The bit 10 is a bit for tightening the phillips screw. The bit 10 is composed of a first shaft portion 101, a second shaft portion 102, and an insertion portion 103. The front end of the first shaft portion 101 is fitted into the cross groove of the screw and the other portion of the first shaft portion 101 has a circular shape in cross section as viewed in the axial direction.

The second shaft portion 102 has a circular shape in cross section as viewed in the axial direction and has a diameter larger than that of the first shaft portion 101. [ The second shaft portion 102 is tapered toward the first shaft portion 101 side.

The insertion portion 103 is plate-shaped, and has a rectangular shape in plan view. The insertion portion 103 has a first surface 1031 which is flat along the axial direction and a second surface 1032 which is also flat along the axial direction. The insertion section 103 also has a hole 1033 that penetrates the insertion section 103 from the first surface 1031 toward the second surface 1032. [

The hole 1033 is an example of a concave portion to which a first sphere 34 to be described later is caught and a concave portion to which the second sphere 35 is caught. The center axis of the hole 1033 intersects the central axis of the bit 10.

4 (a) is a front view of the motor 30, and Fig. 4 (b) is an enlarged view of an end portion of the shaft 31 of the motor 30. Fig. 4 4 (d) is a view showing an end portion of the shaft 31 and a section of a component disposed at the end portion of the shaft 31. As shown in Fig.

A bit connector is formed by the shaft 31, the first sphere 34, the second sphere 35 and the third detent ring 38. The shaft 31 is a rotary shaft formed by machining a cylindrical metal and is provided with an insertion hole 301 formed by cutting along the axial direction of the shaft 31 at the front end. The cross section of the insertion port 301 is circular. One end of the shaft 31 with the insertion port 301 therebetween is referred to as a first end 310 and the other end of the shaft 31 through which the insertion port 301 is inserted is referred to as a second end 320. [ Quot;

The first end 310 and the second end 320 are provided with a groove 302 and a groove 303 along the circumferential direction of the shaft 31. In the first end portion 310, a hole 304A through which the first sphere 34 is inserted is provided between the groove 302 and the groove 303. In the second end portion 320, And a hole 304B through which the two balls 35 are inserted is provided between the groove 302 and the groove 303. The hole 304A and the hole 304B have a circular shape when viewed in the radial direction of the shaft 31. The diameter of the shaft 31A on the side of the center axis of the shaft 31 Is smaller than the diameter of the outer peripheral side of the shaft (31).

The first sphere 34 and the second sphere 35 are fixtures for supporting the bit 10, and are metal spheres. The first sphere 34 is inserted into the hole 304A and the second sphere 35 (second sphere) is inserted into the hole 304B (second hole). The diameter of the first sphere 34 is larger than the diameter of the center axis of the hole 304A and the diameter of the second sphere 35 is larger than the diameter of the hole 304B on the center axis side.

The first stop ring 36 is fitted into the groove 302 and the second stop ring 37 is fitted into the groove 303 as shown in Fig. 4 (d), a third stop ring 38 is sandwiched between the first stop ring 36 and the second stop ring 37. As shown in Fig.

The first detent ring 36 and the second detent ring 37 are parts for preventing the third detent ring 38 from moving in the axial direction of the shaft 31. The first detent ring 36 and the second detent ring 37 are so-called C rings, which are made of metal and have a shape of the letter C as viewed in the axial direction.

The third stop ring 38 is a component for pressing the first sphere 34 and the second sphere 35 in the direction of the central axis of the shaft 31, that is, in the direction of the holes 304A and 304B. The third stop ring 38 is made of metal, and the shape seen from the axial direction is in the shape of alphabet C. The third stop ring 38 has elasticity and elastically deforms in the direction of the inner diameter or the outer diameter. Since the outer diameter of the first detent ring 36 and the second detent ring 37 is larger than the outer diameter of the third detent ring 38, the movement of the third detent ring 38 toward the end side is prevented.

Fig. 5 is a view for explaining the operation when the bit 10 is mounted on the screw fastening device 1. Fig. 5A, in the state where the insertion portion 103 is not positioned in the groove 302, the first sphere 34 inserted in the hole 304A is inserted into the third stop ring And the second sphere 35 inserted into the hole 304B is also pushed by the third stop ring 38 to push the shaft 31 toward the central axis of the shaft 31 by being pushed by the third stop ring 38. [ And protrudes toward the center shaft side. When the bit 10 is moved backward from the state shown in Fig. 5 (a) in order to mount the bit 10 to the screw fastening device 1, the insertion portion 103 enters the groove 302, The portion 103 reaches between the first sphere 34 and the second sphere 35. When the bit 10 is further moved backward, the first surface 1031 pushes the first sphere 34 toward the outer peripheral side of the shaft 31, and the second surface 1032 pushes the second sphere 35 The insertion portion 103 is pushed to the outer peripheral side of the shaft 31 so as to be inserted between the first sphere 34 and the second sphere 35 as shown in Fig. 5 (b).

When the bit 10 further moves backward from the state shown in Fig. 5 (b), the hole 1033 reaches between the first sphere 34 and the second sphere 35. When the hole 1033 reaches between the first sphere 34 and the second sphere 35, the first sphere 34 and the second sphere 35 are separated by the third stop ring 38 from the holes 1033 ). 5 (c), a part of the first sphere 34 protrudes from the hole 304A and enters the hole 1033, and a part of the second sphere 35 comes out of the hole 304B And protrudes into the hole 1033. This causes the first and second spheres 34 and 35 to engage with the hole 1033 and the bit 10 is held between the first and second spheres 34 and 35, (c). When the shaft 31 rotates from the state shown in Fig. 5 (c), the first sphere 34 and the second sphere 35 rotate while supporting the inserting portion 103.

5 (c), when the bit 10 is pulled out from the state of FIG. 5 (c), the first face 1031 comes in contact with the first sphere 34 And the second surface 1032 pushes the second sphere 35 toward the third stop ring 38 so that the insertion portion 103 presses against the first stop ring 38 as shown in Figure 5 (b) And enters between the sphere 34 and the second sphere 35. 5 (b), the insertion portion 103 is detached from the space between the first sphere 34 and the second sphere 35, ) State, and the bit 10 can be removed from the screw fastening device 1. [0050]

Further, when the bit 10 is mounted on the screw fastening device 1, by moving the screw fastening device 1 in the axial direction of the bit 10 with respect to the fixed bit 10, May be positioned in the groove 302. When the bit 10 is removed from the screw fastening device 1, the bit 10 is fixed and the screw fastening device 1 is moved in the axial direction of the bit 10, May be removed from the groove 302.

[Modifications]

Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, but can be implemented in various other forms. For example, the present invention may be implemented by modifying the above-described embodiment as follows. The above-described embodiment and the following modifications may be combined.

In the above-described embodiment, the screw fastening device 1 is a sucking type screw fastening device. The bit 10 may be configured to suck a screw by a magnetic force, . In the above-described embodiment, the bit 10 corresponds to a crisscross groove screw. However, even if the tip of the bit 10 is fitted into the groove of the screw corresponding to the slotted screw good. Further, the bit 10 does not correspond to a screw, and may be another shape such as a drill.

In the above-described embodiment, the component inserted into the hole 304A and the hole 304B to support the bit 10 may not be a sphere. For example, as shown in Fig. 6A, a fin 50 having one end of a cylinder formed into a hemispherical shape is inserted into the holes 304A and 304B, and the hemispherical portion is inserted into the hole 1033 So that the bit 10 is supported. As shown in Fig. 6B, the pin 51 having one end of the cylinder processed into a conical shape is inserted into the hole 304A and the hole 304B, and the conical portion is inserted into the hole 1033 And the bit 10 may be supported by engaging.

Although the hole 304A and the hole 304B have a circular shape when viewed in the radial direction of the shaft 31 in the above embodiment, the shape of the hole is not limited to a circular shape. For example, the shape of the shaft 31 in the radial direction may be a polygon such as a square, a hexagon, or an octagon.

In the above-described embodiment, the portion of the insertion portion 103 which is engaged with the first sphere 34 and the second sphere 35 is the hole 1033, but the first sphere 34 and the second sphere 35, The portion engaging with the through hole 35 may not be a through hole.

7, the insertion portion 103 includes a concave portion 1034A into which a part of the first sphere 34 enters, a concave portion 1034B into which a part of the second sphere 35 enters, . The shape of the concave portion 1034A and the concave portion 1034B when viewed in the depth direction may be a circular shape or a polygonal shape.

In the above-described embodiment, the shaft 31 is formed by machining a cylindrical metal, but it is also possible to process a metal multi-prism having a polygonal shape when viewed in the axial direction to form the insertion hole 301, the hole 304A, 304B may be provided. In addition, even when the shape of the shaft 31 is polygonal when viewed in the axial direction, the central axis of the shaft 31 passes through the insertion port 301. [

The first sphere 34, the second sphere 35 and the third stop ring 38 are separate components. However, the first sphere 34, the second sphere 35, And the third detent ring 38 may be integrated.

In the above-described embodiment, the bit 10 is connected to the shaft 31 of the motor 30. However, the present invention is not limited to this configuration. For example, one end of the rotating shaft connected to the shaft 31 is machined in the same manner as the end of the shaft 31 of the embodiment described above, and the first and second spheres 34 and 35, And the third stop ring 38 may be used to support the bit 10.

In the above-described embodiment, the first end portion 310 has the hole 304A and the second end portion 320 has the hole 304B. However, the present invention is not limited to this configuration. For example, the bit 10 may be supported by either the first sphere 34 or the second sphere 35 without providing either the hole 304A or the hole 304B.

The bit connector of the present invention comprises a shaft having an insertion port for inserting a bit along a central axis and having at least one hole extending from an outer circumferential surface to the insertion port; A fixture disposed in the at least one hole so as to be movable in a direction intersecting the center axis and a stop ring having elasticity and pressing the fixture in the direction of the center axis.

The air sucked from the periphery of the tip of the bit 10 is discharged from the rear cover 15 to the outside of the screw tightening apparatus 1. The tube is connected to the passage 141, The air may be sucked by a pump. Further, a tube may be connected to the passage 131 without providing the passage 141, and air in the tube may be sucked by a pump.

In the embodiment described above, the first sphere 34 and the second sphere 35 are made of metal, but they are not limited to metal, and other materials such as synthetic resin may be processed. The first detent ring 36, the second detent ring 37 and the third detent ring 38 may be formed by processing other materials such as synthetic resin instead of metal.

1: Screw tightening device,
10: bit,
11A: a first cover,
11B: second cover,
12: retainer,
13: Motor mounting mount,
14: Body case,
15: rear cover,
16: Connection joint,
17: O-ring holder,
30: motor,
31: shaft,
34: First,
35: second district,
36: first stop ring,
37: second stop ring,
38: third stop ring,
103: insertion portion,
131: passage,
141: passage,
171: O-ring,
301:
302, 303: groove,
304A, 304B: hole,
310: first end,
320: second end,
1033: hole

Claims (6)

A shaft having an insertion port for inserting a bit along a central axis and having at least one hole extending from an outer circumferential surface to the insertion port;
A fastener disposed in the at least one hole such that a part of the fastener is positioned in the insertion port in a state where the bit is not inserted and is movable in a direction crossing the center axis;
A bit connector having a retaining ring that resiliently urges the fastener in the direction of the central axis. The method according to claim 1,
Wherein the at least one hole includes two holes facing each other with the central axis interposed therebetween,
And one of said fasteners is disposed in each hole. 3. The method according to claim 1 or 2,
On the outer circumferential surface, two grooves are formed along the circumferential direction, respectively,
An auxiliary stop ring is fitted in each groove,
And the stop ring is fixed to the shaft by two auxiliary stop rings. 4. The method according to any one of claims 1 to 3,
Wherein the fastener is spherical. A shaft provided with an insertion port for inserting a bit along a central axis and having at least one hole extending from an outer circumferential surface to the insertion port; a fixture disposed in the at least one hole so as to be movable in a direction crossing the central axis; A bit connector having a detent ring for pressing the fixture in the direction of the central axis,
The bit being fixed to the shaft by the concave portion being caught by the fixing member,
And a driving unit for rotating the shaft. 6. The method of claim 5,
A cover for covering the bit,
Further comprising a case having the cover fixed thereon and accommodating the driving portion therein and having a passage passage communicating with the gap,
And the air in the passage is sucked and discharged out of the case.

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