JP2020066091A - driver - Google Patents

Abstract

To make it hard for a driver having a plate-like end part to fall off from a screw.SOLUTION: A driver for turning a screw having a recess has: a grip part which a user using the driver grips; an axial part connected to the grip part; plate-like blades (a first blade 21 and a second blade 22) formed at an end of the axial part. The blades 21, 22 have: projections 211, 221 formed on the surface; and a cavity 213 and a cavity 223 whose shapes change in the way that width in the state that they are inserted in recesses of a screw becomes smaller than width in the state that they are not inserted.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a screwdriver for rotating a screw.

  A driver is known in which an elastic portion is formed in order to make it difficult for the screw to drop (see, for example, Patent Document 1).

Japanese Utility Model Publication No. Sho 53-054495

  The driver described in Patent Document 1 is a Torx wrench corresponding to a Torx (registered trademark) screw having a hexagonal star-shaped screw hole, and its tip has a hexagonal prism shape. The driver is configured such that one side wall of the hexagonal prism is deformed by forming a groove in the vicinity of the one side wall of the hexagonal prism.

  When the tip of the driver has a hexagonal prism shape, a groove can be formed in the tip portion of the driver to divide the hexagonal prism into a plurality of regions to form an elastic portion. However, in the case where the tip portion is plate-like, such as a flat-blade screwdriver, if the groove is formed in the tip portion, sufficient strength cannot be ensured, and it is difficult to make it difficult to drop the screw. There are many applications in which the Torx screw cannot be used, and it has been required that even a driver other than the Torx screwdriver having a plate-shaped tip portion should have difficulty in dropping the screw.

  Then, this invention is made | formed in view of these points, and an object of this invention is to make it difficult for a screw to fall from the driver which has a plate-shaped front-end | tip part.

  A screwdriver of the present invention is a screwdriver for rotating a screw having a recessed portion, and a gripping portion gripped by a user who uses the driver, a shaft portion coupled to the gripping portion, and a tip end of the shaft portion. And a plate-shaped blade portion formed, the blade portion, the protrusion formed on the surface, the width in the state of being inserted into the recessed portion, than the width in the state not inserted into the recessed portion. And a cavity whose shape changes to become smaller.

  The protrusion may be formed in a tapered shape in which the thickness of the blade portion on the tip side is smaller than the thickness on the opposite side.

  The blade portion may be formed of a biocompatible resin material, and a region of the shaft portion other than the blade portion may be formed of a resin other than the biocompatible resin material.

  According to the present invention, it is possible to make it difficult for a screw to drop from a driver having a plate-shaped tip.

It is a perspective view showing the appearance of a driver. It is a figure which shows an example of the shape of the screw used as the object to fasten using a driver. It is a front view which shows the member structure of a driver. It is the sectional view on the AA line of a driver. It is a perspective view which shows the structure of the periphery of the blade part formed in the front-end | tip of the 2nd shaft part. It is a figure which shows the structure of a 2nd shaft part. It is an enlarged view of the peripheral part of the 1st blade part which a 2nd axis part has.

[Configuration of driver 1]
FIG. 1 is a perspective view showing the external appearance of the driver 1. FIG. 2 is a diagram showing an example of the shape of the screw 3 to be tightened using the driver 1. The screw 3 has a shaft portion 31, a head portion 32, and a concave portion 33.

  FIG. 3 is a front view showing a member configuration of the driver 1. FIG. 4 is a cross-sectional view of the driver 1 shown in FIG. The driver 1 is used to rotate a screw 3 having a recess. The driver 1 is, for example, a flat-blade screwdriver or a flat-blade driver having a plate-shaped blade portion formed at its tip.

  The driver 1 has a first grip portion 11, a second grip portion 12, and a shaft portion 13. The first grip portion 11, the second grip portion 12, and the shaft portion 13 are formed of, for example, hard resin, but may be formed of other members such as metal and wood. As shown in FIG. 1, the shaft portion 13 has a first shaft portion 131 and a second shaft portion 132.

  The first grip portion 11 and the second grip portion 12 are portions gripped by a user who uses a driver. The first grip portion 11 is a hollow member formed in a long shape, and the shaft portion 13 is coupled to one end thereof. The second grip portion 12 is provided on the side opposite to the side of the first grip portion 11 to which the shaft portion 13 is coupled.

  As shown in FIG. 4, the first grip portion 11 has a side wall 111, a coupling portion 112, and a shaft fixing portion 113. The coupling portion 112 is a portion that couples the second grip portion 12 with the second grip portion 12 in a rotatable state with respect to the first grip portion 11. The coupling portion 112 is formed, for example, in an annular shape, and by fitting in the groove formed in the coupling portion 122 of the second grip portion 12, the second grip portion 12 does not separate from the first grip portion 11. Allows you to rotate.

  The shaft fixing portion 113 is a portion that fixes the shaft portion 13. The shaft fixing portion 113 fixes the shaft portion 13 to the first grip portion 11 in a state where the shaft portion 13 does not rotate with respect to the first grip portion 11.

  The second grip portion 12 has a side wall 121 and a coupling portion 122. The side wall 121 is formed in a dome shape, for example. The coupling portion 122 has a cylindrical shape and extends from the inner wall of the tip portion of the side wall 121. The joint portion 122 is rotatably fitted to the joint portion 112 and rotates inside the first grip portion 11.

  The shaft portion 13 is rotatably coupled to the first grip portion 11 with the second grip portion 12 fixed. Specifically, the first shaft portion 131 is fixed to the first grip portion 11, and the side of the first shaft portion 131 opposite to the side fixed to the first grip portion 11 is coupled to the second shaft portion 132. is doing. One end of the second shaft portion 132 is coupled to the first shaft portion 131, and a plate-shaped blade portion that fits with the screw 3 is provided at a tip opposite to the one end coupled to the first shaft portion 131. Are formed.

  For example, the user can rotate the shaft portion 13 by rotating the first grip portion 11 with a finger while the second grip portion 12 is in contact with the palm. With the driver 1 configured in this manner, the user can easily rotate the shaft portion 13 and tighten the screw 3 even when working in a place where it is difficult to rotate the arm.

[Blade structure]
FIG. 5 is a perspective view showing the structure around the blade portion formed at the tip of the second shaft portion 132. FIG. 6 is a diagram showing the structure of the second shaft portion 132. FIG. 7 is an enlarged view of a peripheral portion of the first blade portion 21 included in the second shaft portion 132.

  As shown in FIG. 5, a plate-shaped first blade portion 21, a second blade portion 22, a third blade portion 23, and a fourth blade portion 24 are formed at the tip of the second shaft portion 132, respectively. FIG. 6A is a diagram showing the second shaft portion 132 viewed from the tip side of the driver 1. FIG. 6B is a diagram showing the second shaft portion 132 viewed from the third blade portion 23 side. FIG. 6C is a diagram showing the second shaft portion 132 viewed from the first blade portion 21 side.

  The first blade portion 21 and the second blade portion 22 are formed such that their longitudinal side walls are located on the same straight line. The third blade portion 23 and the fourth blade portion 24 are positioned so that their longitudinal side walls are located on a straight line orthogonal to the straight line on which the longitudinal side walls of the first blade part 21 and the second blade part 22 are located. Has been formed. In the example shown in FIG. 6A, the first blade portion 21, the second blade portion 22, the third blade portion 23, and the fourth blade portion 24 form a cross-shaped convex portion.

  As shown in FIG. 6A, a protrusion 211 and a protrusion 212 are formed on the surface of the first blade portion 21. A cavity 213 is formed between the protrusion 211 and the protrusion 212. The shape of the cavity 213 when viewed from the tip side of the second shaft portion 132 is, for example, an ellipse, but may be a rectangle.

  The thickness of both sides of the cavity 213 in the lateral direction of the first blade portion 21 is such that the side wall of the first blade portion 21 is deformed by the force pressing the inside of the second shaft portion 132 to the protrusion 211 and the protrusion 212. It is thinly formed. Therefore, when the first blade portion 21 is inserted into the recess 33 of the screw 3 and the protrusion 211 and the protrusion 212 contact the inner wall of the recess 33 to press the protrusion 211 and the protrusion 212, the shape of the cavity 213 becomes The width in the state of being inserted into the recess 33 changes so as to be smaller than the width in the state of not being inserted into the recess 33. As a result, the side wall of the first blade portion 21 bends inward of the cavity 213, so that a force that causes the side wall of the first blade portion 21 to return to the outside is generated. The screw 3 becomes difficult to separate from the driver 1 by being pressed against.

  The protrusions 211 and 212 are formed, for example, at the center position in the longitudinal direction of the cavity 213. By forming the protrusions 211 and 212 in this manner, the side wall of the first blade portion 21 is easily bent.

  Similarly, a protrusion 221 and a protrusion 222 are formed on the second blade portion 22. A cavity 223 is formed between the protrusion 221 and the protrusion 222. The shape of the cavity 223 when viewed from the tip end side of the second shaft portion 132 is, for example, an ellipse like the cavity 213, but may be a rectangle. The protrusion 221 and the protrusion 222 are formed, for example, at a central position in the longitudinal direction of the cavity 223.

  The wall thickness on both sides of the cavity 223 in the lateral direction of the second blade portion 22 is such that the side wall of the second blade portion 22 is deformed by the force pressing the inside of the second shaft portion 132 to the protrusion 221 and the protrusion 222. It is thinly formed. Therefore, when the second blade portion 22 is inserted into the recess 33 of the screw 3 and the protrusion 221 and the protrusion 222 contact the inner wall of the recess 33 to press the protrusion 221 and the protrusion 222, the shape of the cavity 223 becomes The width in the state of being inserted into the recess 33 changes so as to be smaller than the width in the state of not being inserted into the recess 33. As a result, the side wall of the second blade portion 22 bends inward of the cavity 223, so that a force that causes the side wall of the second blade portion 22 to return to the outside is generated. Pressed against. Since the second blade portion 22 has the same configuration as the first blade portion 21 in this way, the screw 3 becomes more difficult to separate from the driver 1.

  Here, at least a partial region of the protrusion 211, the protrusion 212, the protrusion 221, and the protrusion 222 is on the tip side of the first blade portion 21 and the second blade portion 22 like the protrusion 211 and the protrusion 212 shown in FIG. 7. The thickness may be smaller than the thickness on the opposite side. That is, the protrusion 211, the protrusion 212, the protrusion 221, and the protrusion 222 have the smallest thickness on the side inserted into the screw 3, and the largest thickness on the opposite side to the side inserted into the screw 3.

  Since the protrusion 211, the protrusion 212, the protrusion 221, and the protrusion 222 are formed in a tapered shape in this manner, the user can smoothly insert the shaft portion 13 into the recess 33 of the screw 3. Even when the width of the recess 33 of the screw 3 varies, the protrusion 211, the protrusion 212, the protrusion 221, and the protrusion 222 contact the inner wall of the recess 33 at positions corresponding to the width of the recess 33. It is possible to reduce the influence of the variation of.

[Material of shaft 13]
The first shaft portion 131 and the second shaft portion 132 may be formed of different members. For example, the first blade portion 21, the second blade portion 22, the third blade portion 23 and the fourth blade portion 24 are formed of a biocompatible resin material, and the first blade portion 21, the second blade of the shaft portion 13 Areas other than the portion 22, the third blade portion 23, and the fourth blade portion 24 may be formed of a resin other than the biocompatible resin material. The biocompatible resin material is, for example, polylactic acid. The entire second shaft portion 132 may be made of a biocompatible resin material, and the first shaft portion 131 may be made of a resin other than the biocompatible resin material.

  Since the entire second shaft portion 132, or the first blade portion 21, the second blade portion 22, the third blade portion 23, and the fourth blade portion 24 are formed of a biocompatible resin material, the screw 3 is fractured. When it is used by being embedded in a human body such as in the treatment of the above, some regions of the first blade portion 21, the second blade portion 22, the third blade portion 23 and the fourth blade portion 24 are scraped and remain in the body. Even if it does, it can prevent the adverse effect on the body.

[Modification]
In the above description, the case where the second shaft portion 132 has the first blade portion 21, the second blade portion 22, the third blade portion 23, and the fourth blade portion 24 is illustrated, but the second shaft portion 132 is You may have at least 1 of the 1st blade part 21, the 2nd blade part 22, the 3rd blade part 23, and the 4th blade part 24. For example, the driver 1 is a flathead screwdriver, the second shaft portion 132 has the first blade portion 21 and the second blade portion 22, and the third blade portion 23 and the fourth blade portion 24 are not provided. Good.

  Moreover, in the above description, the case where the 1st blade part 21 and the 2nd blade part 22 have a protrusion in a some side wall was illustrated, but the 1st blade part 21 and the 2nd blade part 22 have two side walls. You may have a protrusion only in one side. Further, protrusions may be formed on all of the first blade portion 21, the second blade portion 22, the third blade portion 23, and the fourth blade portion 24.

[Effect of Driver 1]
As described above, the driver 1 is formed at the first grip portion 11 for the user who uses the driver 1 to grip, the shaft portion 13 coupled to the first grip portion 11, and the tip of the shaft portion 13. And a plate-shaped first blade portion 21 and a second blade portion 22. The first blade portion 21 and the second blade portion 22 have a protrusion 211, a protrusion 212, a protrusion 221, and a protrusion 222 formed on the surface, and a cavity 213 and a cavity 223. The shape of each of the cavities 213 and 223 is changed so that the width of the screw 3 inserted into the recess 33 is smaller than the width of the screw 3 not inserted into the recess 33. As a result, the sidewalls of the first blade portion 21 and the second blade portion 22 bend inside the cavities 213 and 223, respectively, so that the sidewalls of the first blade portion 21 and the second blade portion 22 try to return to the outside. The force to do occurs. Therefore, when the protrusion 211, the protrusion 212, the protrusion 221, and the protrusion 222 are pressed against the recess 33 of the screw 3, the screw 3 becomes difficult to separate from the driver 1.

  Further, the protrusion 211, the protrusion 212, the protrusion 221, and the protrusion 222 are formed in a tapered shape in which the thickness of the first blade portion 21 and the second blade portion 22 on the tip side is smaller than the thickness on the opposite side. With the driver 1 thus configured, the user can smoothly insert the shaft portion 13 into the recess 33 of the screw 3. Even when the width of the recess 33 of the screw 3 varies, the protrusion 211, the protrusion 212, the protrusion 221, and the protrusion 222 contact the inner wall of the recess 33 at positions corresponding to the width of the recess 33. It is possible to reduce the influence of the variation of.

  In addition, the first blade portion 21, the second blade portion 22, the third blade portion 23, and the fourth blade portion 24 are formed of a biocompatible resin material. With the driver 1 configured in this way, when the screw 3 is used by being embedded in the human body for treatment of a fracture or the like, the first blade portion 21, the second blade portion 22, and the third blade portion 23 are used. Even if a part of the area of the fourth blade portion 24 is scraped off and remains in the body, it is possible to prevent the adverse effect on the body.

  The first grip 11, the second grip 12, and the shaft 13 are made of, for example, hard resin. When the first grip portion 11, the second grip portion 12, and the shaft portion 13 are formed of resin, the driver 1 can be manufactured at low cost. Therefore, even when the screwdriver 3 is used for embedding the screw 3 in the human body, it can be easily replaced with a new screwdriver 1 even if the screwdriver 3 is used for blood adhesion. Suitable for

  Although the present invention has been described using the embodiments, the technical scope of the present invention is not limited to the scope described in the above embodiments, and various modifications and changes can be made within the scope of the gist thereof. is there. For example, the specific embodiment of the distribution / integration of the device is not limited to the above-described embodiment, and all or a part thereof may be functionally or physically distributed / integrated in arbitrary units. You can Further, a new embodiment that occurs due to an arbitrary combination of a plurality of embodiments is also included in the embodiment of the present invention. The effect of the new embodiment produced by the combination also has the effect of the original embodiment.

DESCRIPTION OF SYMBOLS 1 screwdriver 3 screw 11 1st holding part 12 2nd holding part 13 shaft part 21 1st blade part 22 2nd blade part 23 3rd blade part 24 4th blade part 31 shaft part 32 head part 33 recessed part 111 side wall 112 coupling part 113 shaft fixing part 121 side wall 122 coupling part 131 first shaft part 132 second shaft part 211 protrusion 212 protrusion 213 cavity 221 protrusion 222 protrusion 223 cavity

Claims (3)

A driver for rotating a screw having a recess,
A grip portion to be gripped by a user who uses the driver,
A shaft portion coupled to the grip portion,
A plate-shaped blade portion formed at the tip of the shaft portion,
Have
The blade portion has a protrusion formed on the surface and a cavity whose shape is changed so that the width when inserted in the recess is smaller than the width when not inserted in the recess. Characteristic driver. The projection is characterized in that the thickness of the tip side of the blade portion is formed in a tapered shape smaller than the thickness of the opposite side,
The driver according to claim 1. The blade portion is formed of a biocompatible resin material, the region of the shaft portion other than the blade portion is formed of a resin other than the biocompatible resin material,
The driver according to claim 1 or 2.

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