JP3119826B2 - Screw fastening tool - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a screw tightening tool, and more particularly to a screw tightening tool suitable for a surgical operation for tightening a screw in a narrow place and a place where visual observation is difficult.

[0002]

2. Description of the Related Art Screw fasteners (hereinafter referred to as "drivers") are used for many purposes, but there are cases where they are also used, for example, for surgical operations. More specifically, a bone having a slit on the head and having a shape as shown in FIG. 5 made of a material such as metal, ceramic, degradable or non-degradable plastic, or hydroxyapatite is used to replace the broken bone. There is a use as a tool when inserting and connecting and reinforcing a damaged part.

As such a driver for a surgical operation, for example, a shaft 2 fixed to a grip 203 shown in FIG.
01 is a driver 20 having a minus cross section.
0 is common. Examples of using such a driver are shown in FIGS. FIG. 7 shows a state in which the bone graft 301 is implanted for the spine 300 injury. Also, FIG.
This shows how the screws are fixed in ligament reconstruction.

A method of using the driver 200 will be described with reference to FIG. 7. First, the tip of the screwdriver is engaged with a slot formed on the head of the screw, and the screw tip is provided in advance on a bone or the like. Insert into the screw hole 302. Then, the driver is rotated with the tip of the screwdriver engaged with the edge of the screw head, and the screw is screwed and fixed. Thereafter, the tip of the driver is released from the sliding, and the operation is completed.

[0005]

However, according to the above-mentioned conventional driver, there is a problem that when the screw is screwed in, the engagement between the tip of the driver and the thread of the screw is easily released. If the tip of the screwdriver and the screw of the screw are easily disengaged in this way, the operation of engaging the screwdriver with the screw must be repeated many times. In the case of a deep portion, it is not easy to re-engage when the single engagement is released, and this may hinder the smooth progress of the operation.

Further, if the tip of the screwdriver is disengaged from the thread of the screw before the tip of the screw is inserted into a predetermined screw hole or the like, the screw falls and slips into the body, resulting in a surgical operation. It can hinder progress. On the other hand, when the material of the screw is made of metal, it is generally practiced to prevent the driver tip from being disengaged from the screw head by magnetic force, but ceramic, degradable or non-degradable plastic is generally used. When the screw is made of a non-metallic material such as hydroxyapatite, it is impossible to maintain the engagement by the magnetic force.

On the other hand, a mechanism for holding the screw at the tip of the driver may be provided. However, when the screw is fixed in a narrow portion or a deep portion inside the human body, immediately after the work is completed, Must be disengaged from the driver tip and the screw head. The present invention has been made in view of the above-described points, and it is difficult to disengage the head of the screw and the tip of the driver regardless of the screw material. It is an object of the present invention to provide a driver capable of disengaging a head and a driver tip.

[0008]

In order to achieve the above-mentioned object, a screw fastening tool according to the present invention comprises: a holding member for holding an outer periphery of a screw head at a distal end of a shaft having a base end fixed to a grip portion; An engaging body engaged with the screw head is provided in a state in which the engaging body is urged in a direction protruding from the tip of the holding body by an elastic machine inside the holding body. The relative movement range is regulated by the engagement between the locking pin formed on the other side and the guide groove formed on the other side, and when the locking pin is located on one groove end side of the guide groove, the engaging body is The engaging member is in a first position in which the engaging member is engaged with the screw head while the outer periphery of the screw head is held by the holding member and the locking pin is located on the other groove end side of the guide groove. When doing, the engaging body protrudes out of the holding body,
In a state where the engaging body is engaged with the screw head in a state where the screw head is not held by the holding body, and when the grip portion is rotated in the screw tightening direction in the first and second postures, the locking pin and By the engagement with the groove end, the rotating power is transmitted to the engagement body, the screw is tightened by the engagement with the engagement body, and when the rotation operation is performed in the opposite direction, the locking pin moves in a direction away from the groove end. At a position shifted by a predetermined amount from the first posture, the locking pin is configured to be urged to move toward the other groove end by the elastic restoring force of the elastic machine.

Further, the holding body is characterized in that the opening has a cylindrical structure whose diameter can be expanded.

Further, the guide groove is formed in a U-shape or an E-shape.

[0011]

[0012]

FIG. 1 is an external view of a driver 1 which is an example of a screw fastener according to the present invention. As shown in the figure, the driver 1 has a grip portion 10 and a long shaft member 2 whose base end is screwed into the grip portion 10 and fixed with a fixing screw 30.
0, the rotational force of the grip 10 is engaged with the head slot 101 of the screw 100 and
An engaging body 40 having a protruding piece 41 (see FIG. 2) for transmitting the screw 100 and a holding body 50 for holding the outer periphery of the head of the screw 100.
Are provided.

FIG. 2 is an exploded perspective view showing the structure of the tip of the shaft 20 in detail. As shown in FIG.
The leading end of the cylindrical member 21 has a first cylindrical portion 21, a brim portion 22, in which a guide groove 210 is formed in order from the base end side of the shaft, and a holding body 50 in which a plurality of vertical grooves 231 are formed from the tip to the middle. A second cylindrical portion 23 is formed. Further, a hole 60 is formed from the tip of the second cylindrical portion 23 to the middle of the shaft body 20 through the first cylindrical portion 21, and a columnar shape in which a protruding piece 41 is formed at the tip in the hole 60. Are engaged.

A coil spring 70 is provided between the engagement body 40 and the bottom of the hole 60 to urge the engagement body 40 to project outside the hole 60. Further, a locking pin 42 that engages with the guide groove 210 protrudes from a peripheral portion of the engagement body 40, and the locking pin 42 together with the guide groove 210 regulates a movement range of the engagement body 40. 80. The manner in which the regulating section 80 regulates the movement range of the engagement body 40 will be described later.

When assembling the driver 1,
The locking pin 42 is attached last. That is, the engaging body 40 is inserted into the hole 60 together with the coil spring 70, the position of the engaging body 40 in the hole 60 is appropriately determined, and then the locking pin 42 is welded to the outer periphery of the engaging body 40 through the guide groove 210. To attach. The hole 60 in the second cylindrical portion 23 is provided with the screw 1
It has an inner diameter that is the same as or slightly smaller than the outer diameter of the head of 00, so that the screw head is held in a forced-fit configuration. However, since a plurality of vertically divided grooves 231 are formed in the second cylindrical portion 23, the diameter can be increased by applying an external force. Therefore, when the screw 100 is pressed into the hole 60 with an appropriate force, the head is
The screw head can be inserted into the cylindrical portion 23, and when the action of the external force is released in that state, the screw head is held by the diameter reducing force of the second cylindrical portion 23.

An auxiliary member 90 is provided on the outer periphery of the second cylindrical portion 23.
Is fitted. The auxiliary member 90 has a configuration in which a vertically split groove 91 is formed in a part of the cylindrical body as shown in FIG. 2, and can be expanded so as not to hinder the expansion of the second cylindrical portion 23. The holding body 50 whose diameter is to be increased is slightly tightened in the inner circumferential direction to improve the diameter reducing force of the holding body of the screw. The auxiliary member 90 is positioned by the collar portion 22 so as not to enter the rear of the shaft. Although the auxiliary member 90 is not always necessary, it is more preferable to increase the holding force of the holding body 50.

The holding of the screw by the holding body 50 restrains the screw head with such a force that the screw does not fall off the engaging body, and hinders rotation of the engaging body while holding the screw. Not something. The guide groove 210 is
As shown in the figure, the third groove portion 210c extending in the axial direction of the first cylindrical portion 21 is connected to the third groove portion, and the direction of screwing in the screw (right-hand screw direction in the drawing) is opposite from each connection end. It has a U-shape including first and second groove portions 210a and 210b extending.

FIG. 3 is an enlarged view of the tip portion of the driver 1. With reference to this drawing, the regulation of the range of movement of the engagement body 40 by the regulation portion 80 (the guide groove 210 and the locking pin 42) will be described. As shown in FIGS. 3A and 3B, when the locking pin 42 is located at one end of the first and second groove portions 210a and 210b that is connected to the third groove portion, the engagement body 40 is in the first position. , Can be rotated counterclockwise with respect to the shaft body 20 by an angle corresponding to the length of the second groove portions 210a and 210b. Then, the locking pin 42 is connected to the first and second groove portions 210.
When the left end of the groove is reached in the drawings a and 210b, the engagement pin 42 comes into contact with the peripheral wall of the groove, whereby the movement of the engaging body 40 in the distal direction and the rotation in the counterclockwise screw direction are restricted. Thereby, the engaging body 40 is fixed at this position during the screwing operation, and rotates integrally with the shaft body 20 in the right-handed screw direction.

3 (a) and 3 (b).
When the engagement body 40 is at the position shown in FIG.
It is movable in the axial direction of the shaft body 20 by the length of 10c.
It is important to set the positions of both ends of the third groove portion 210c, in other words, the positions of the first groove portion 210a and the second groove portion 210b. In the present embodiment, the positions are set as follows.

That is, when the locking pin 42 is located in the first groove portion 210a as shown in FIG.
In the state where the projecting piece 41 at the tip protrudes axially forward from the tip of the second cylindrical portion 23, and the thread 101 of the screw 100 is engaged with the projecting piece 41, the screw head is 2
3 and the locking pin 4
3B, when the engaging member 40 is located in the second groove portion 210b as shown in FIG.
The length of the third groove portion 210c is set so that the screw head can take a retracted posture in which the screw head is buried in the second cylindrical portion 23 in a state where the screw head 1 is engaged with the protruding piece 41. .

The operation of the driver 1 having the above configuration will be described. Now, as shown in FIG.
When the screw 10 is located in the groove portion 210a,
When the 0-slit 101 is engaged with the protruding piece 41 and pushed inward of the hole 60, the locking pin 42 is guided by the third groove portion 210c and moves to the second groove portion 210b. When the screw or the grip 10 is rotated at that position, the locking pin 42
Moves to the end of the second groove portion 210b as shown in FIG. Even if the external force acting on the screw is released in this state, the screw 100 does not fall off from the driver 1 because its head is held by the second cylindrical portion 23. Therefore, when the screw tip is inserted into the screw hole provided in the affected part in this state, and the grip 10 is rotated in the direction of the right-hand screw, the screw is held in the stable position held by the second cylindrical portion 23. Going screwed. When the screwing is completed, the grip 10 is slightly rotated in the opposite direction. At this time, since the screw is fixed, the engagement body 40 does not rotate, and only the shaft body rotates. Then, the locking pin 42 moves to the third groove portion 210c, and when the force applied to the driver 1 is loosened, the screw head is moved to the second cylindrical portion 23 by the elastic restoring force of the coil spring 70.
Get out of. As a result, the engagement body 40 instantaneously shifts to a state of releasing the holding. In this state, since the holding of the screw head is released, the driver 1 can be easily detached from the screw, and the operation is completed.

When this operation is completed, the projecting piece 41 is exposed in the direction of the tip of the driver, so that the next screw can be easily engaged. As described above, according to the driver 1, it is difficult to disengage the screw during the screw tightening operation, and when the screw tightening is completed, it is possible to instantaneously shift to a state where the engagement is easily released only by rotating in the opposite direction. Thus, it is excellent in usability in screwing work to a narrow place where visual observation is difficult.

Further, the driver 1 is rotated in the counterclockwise direction as described above, and the screw head is pulled out of the second cylindrical portion 23 (at this time, the locking pin 42 is
It is in the position of (a). When the grip 10 is turned in the right-handed screw direction at that position, the locking pin 42 is
Move to the left end of a. Further, by rotating the grip portion 10 in the direction of the right-hand screw, the screw can be screwed in more reliably.

[Other Matters] Needless to say, the present invention is not limited to the above-described embodiment, but includes the following contents. (A) The shape of the protruding piece 41 of the engaging body 40 is a minus shape. However, the shape is not limited to this, and a plus shape or a hexagonal shape corresponding to the sliding provided on the screw head may be used. Good.

In addition to the case where the screw and the driver tip are engaged in a combination of irregularities, a concave portion having a shape to be engaged with the projection of the screw head is formed in the tip direction of the engaging body, and the screw and the driver tip are formed. May be engaged in a combination of irregularities. (B) Although the spring 70 is used as an elastic machine, the present invention is not limited to this, and rubber or the like having elasticity may be used.

(C) Although the guide groove 210 is provided on the shaft and the locking pin 42 is provided on the engaging body 40, the same function as the driver 1 is exhibited even if the guide groove is provided on the engaging body and the locking pin is provided on the shaft. can do. (D) In the above embodiment, the screwdriver is adapted to be rotated clockwise to tighten the screw. However, the screwdriver is rotated counterclockwise to remove the screw. In order to achieve this, as shown in FIG.
A fourth groove portion 210d orthogonal to 0c and connected to the second groove portion 210b may be provided. The operation is similar to that of the driver 1.

In this way, if the engaging member 40 is engaged with the fixed screw and rotated counterclockwise, the screw can be fixed while the screw head is held by the holding member. In this case, workability can be improved. Further, by adopting such a shape of the guide groove, it is possible to cope with a counterclockwise screwing.

(E) If the tip of the holder is cut into a tapered shape so that the thickness of the holder becomes gradually thinner in the tip direction, even if the engaged screw head has a relatively larger diameter than the diameter of the hole,
It can be easily guided into the holding body. (F) In the above-described embodiment, the structure in which the holding body does not move with respect to the shaft body and the engagement body slides is described. Since the same function as that of the driver 1 can be provided, a structure in which the holding body slides with respect to the shaft body can also be used.

(G) In the above embodiment, the structure in which the screw is held and released from the holding in accordance with the screw tightening operation of the operator has been described. An interlocking mechanism for releasing the holding and releasing the holding may be provided. For example, it is also possible to provide an interlocking mechanism for holding and releasing the screw by the button operation of the operator.

(H) The driver according to the present invention is not limited to a surgical operation, and is also a suitable tool for tightening a screw in a narrow place.

[0031]

As described above, according to the screw tightening tool according to the present invention, the holder for holding the outer periphery of the screw head is connected to the tip of the shaft having the base end fixed to the grip portion. Inside the holding body, an engaging body engaging with the screw head is provided in a state where the engaging body is urged by a bullet in a direction protruding from the tip of the holding body, and the engaging body and the holding body are formed on one side. The relative movement range is regulated by the engagement between the locking pin and the guide groove formed on the other side, and when the locking pin is located on one of the guide groove ends, the engaging body is engaged with the holding body. The engaging body is in the first position in which the engaging body is engaged with the screw head while the screw head outer periphery is held by the holding body, and the locking pin is located on the other groove end side of the guide groove. When the engaging body protrudes out of the holding body, the screw head is not held by the holding body In this state, the engaging body is brought into the second position in which it engages with the screw head, and when the grip portion is rotated in the screw tightening direction in the first and second positions, the engagement between the locking pin and the groove end is made. When the rotational power is transmitted to the engaging body, the screw is tightened by the engagement with the engaging body, and when the screw is turned in the opposite direction, the locking pin moves in a direction away from the groove end, and the first pin is moved from the first position. At the position where the fixed movement has occurred, the locking pin is configured to be urged to move in the direction toward the other groove end by the elastic restoring force of the above-mentioned machine, so that the following effects are obtained. That is, in the first posture in which the head of the screw engaged by the engagement body is held by the holding body, the screw tightening operation can be performed by rotating the grip portion, and at the end of the screw tightening operation, When the operator rotates the grip in the direction opposite to the screw tightening direction, the elastic restoring force of the elastic machine acts to retract the holding body relative to the engaging body, and automatically releases the screw holding state. it can. Therefore, when tightening the screw,
The screw can be tightened without dropping off the screws, and the screw tightening operation and the release operation of the screw holding can be performed simply by rotating the grip portion. This is very convenient when screwing work is performed on a narrow part where it is difficult to perform the work.

[0032]

Further, the holding body has a cylindrical structure whose opening can be expanded in diameter, so that the screw can be securely held by the diameter reduction force of the holding body. In order to realize the two states of holding the screw and releasing the screw holding, specifically, a restricting portion for restricting a range of movement of the engaging member with respect to the holding member is provided. The structure can be switched to the protruding posture. This makes it easy to switch between the two states of holding the screw and releasing the screw holding.

[0034]

[Brief description of the drawings]

FIG. 1 is an external view of a driver 1 according to an embodiment.

FIG. 2 is a partially exploded perspective view of the driver 1. FIG.

FIG. 3 is an enlarged view of a tip portion of the driver 1.

FIG. 4 is a view showing another example of a guide groove portion.

FIG. 5 is an external view showing an example of a screw.

FIG. 6 is an external view showing an example of a conventional driver.

FIG. 7 is a schematic diagram showing a usage example of the driver.

FIG. 8 is a schematic view showing another example of a usage example of the driver.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Driver 10 Handle part 20 Shaft 40 Engagement body 41 Protrusion piece 42 Lock pin 50 Holder 60 Hole 70 Coil spring 80 Restriction part 90 Auxiliary member 100 Screw 210 Guide groove 210a First groove part 210b Second groove part 210c Third groove Part 210d fourth groove part

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A 47-26398 (JP, U) JP-A 6-74269 (JP, U) JP-A 58-51970 (JP, U) 16996 (JP, Y1) (58) Field surveyed (Int. Cl. ⁷ , DB name) B25B 23/10

Claims (3)

(57) [Claims] 1. A distal end of a shaft body having a base end fixed to a grip portion.
, A holding body for holding the outer periphery of the screw head is continuously provided,
In the inside of the machine, the engaging body engaging with the screw head is
Provided in a state where it is urged in a direction to protrude from the holder tip
And the engaging body and the holding body are formed on one of
The relative movement is achieved by the engagement between the pin and the guide groove formed on the other side.
The movement range is restricted and one of the guide groove ends
When the locking pin is located on the side,
Part, the outer periphery of the screw head was held by the holder
In the state, the engaging body is in the first posture for engaging with the screw head,
If the locking pin is located on the other groove end side of the guide groove
When the engaging body protrudes outward from the holder, the screw head
The engagement body engages with the screw head in a state where the part is not held.
2 position, screw tightening in 1st and 2nd position
When the grip is rotated in the locking direction, the locking pin and the groove end
The rotational power is transmitted to the engagement body by the engagement of
Tighten the screw by engagement and rotate in the opposite direction
Then, the locking pin moves in the direction away from the groove end,
At a position shifted by a predetermined amount from the posture of
The locking pin moves to the other groove end side due to elastic restoring force
A screw tightening tool characterized in that it is configured to be biased. 2. The holding body has a cylindrical shape whose opening can be expanded in diameter.
The screw fastener according to claim 1, wherein the screw fastener has a structure . 3. The guide groove has a U-shape or a U-shape.
3. The screw fastening tool according to claim 1, wherein the screw fastening tool is formed in a letter shape .