KR102613566B1 - Apparatus for removing screw - Google Patents

Abstract

The present invention relates to a screw removal device. Specifically, according to one embodiment of the present invention, a first body member including a first groove insertion portion; A second body member including a second groove insertion portion and rotatably connected to the first body member about a rotation center extending in one direction, wherein the first groove insertion portion has a first overlapping surface of the first body member. 1 is formed to extend in the longitudinal direction of the groove insertion part, and in the second groove insertion part, a second overlapping surface is formed to face the first overlapping surface and extend in the longitudinal direction of the second groove insertion part, and the first body The member and the second body member are positioned at a first rotational position where the first overlapping surface and the second overlapping surface overlap each other by a predetermined ratio or more in the one direction, or where the first overlapping surface and the second overlapping surface overlap each other at a predetermined ratio or more. A screw removal device may be provided that is placed in a second rotational position where they overlap each other by a smaller ratio, and wherein the first overlapping surface and the second overlapping surface are inclined with respect to an imaginary surface perpendicular to the one direction.

Description

Screw removal device {APPARATUS FOR REMOVING SCREW}

The present invention relates to a screw removal device.

Recently, instruments commonly used when performing fracture and bone correction surgery in the orthopedic field include a locked compression metal plate and a multi-angle locking screw that fixes the locked compression metal plate to the bone. Polygonal locking screws are commonly used with a hexagonal insertion groove formed on the screw head.

After sufficient bone union has occurred through fracture and bone correction surgery or procedures, it may be necessary to remove multiple locking screws and metal plates. Even if bone union does not occur, metal substances must be removed if situations such as infection or breakage of the metal plate occur. .

The biggest problem with using locked compression metal plates and multi-locking screws is that the screw heads of the multi-locking screws are damaged when performing metal removal surgery.

When the metallic multi-locking screw is fixed to the bone and bone union progresses over a certain period of time, the bonding force between the bone and the screw increases. In this case, when removing a polygonal locking screw, the high bonding force between the screw and the bone cannot be overcome, and the polygonal insertion groove formed on the screw head may be crushed and damaged.

If the polygonal insertion groove formed on the screw head of the polygonal locking screw is damaged, it is difficult to remove the screw with a regular screwdriver, so it can be removed using a conventional polygonal locking screw removal driver, or if this method fails, use a special equipment ( There is a problem of having to grind the screw head with a burr and remove the screw.

The conventional polygonal locking screw removal driver is a method of removing the screw by engaging a driver in a polygonal insertion groove formed on the screw head of the polygonal locking screw. At this time, the polygonal locking screw can be released only when the removal driver is aligned exactly perpendicular to the polygonal insertion groove of the screw head and rotated with a certain force and direction.

When a conventional polygonal locking screw removal driver removes a polygonal locking screw, a gap inevitably occurs between the removal driver and the polygonal insertion groove of the screw head. In addition, due to this gap, the adhesion between the polygonal insertion groove of the screw head and the removal driver is reduced, making it difficult to remove the screw, and there is a problem that the removal driver is damaged after several uses.

In addition, in the conventional polygonal locking screw removal driver, the polygonal insertion groove formed on the screw head may be damaged as the adhesion force is reduced due to a gap with the screw. In this case, in the process of removing the screw head of the screw and removing the locking compression metal plate using special equipment (burr), small pieces of metal remain in the patient's body, which are foreign substances that cause inflammation or infection. There is a problem with this.

Korean Patent Publication No. 2021-0006781 (published on January 19, 2021)

Embodiments of the present invention were invented against the above background, and the screw is removed from the screw coupling member to which the screw is coupled without damaging the insertion groove formed in the screw head, and the screw is easily removed from the screw coupling member even if the insertion groove is already damaged. The object is to provide a screw removal device that can be removed from.

According to one aspect of the present invention, a first body member including a first groove insertion portion; A second body member including a second groove insertion portion and rotatably connected to the first body member about a rotation center extending in one direction, wherein the first groove insertion portion has a first overlapping surface of the first body member. 1 is formed to extend in the longitudinal direction of the groove insertion part, and in the second groove insertion part, a second overlapping surface is formed to face the first overlapping surface and extend in the longitudinal direction of the second groove insertion part, and the first body The member and the second body member are positioned at a first rotational position where the first overlapping surface and the second overlapping surface overlap each other by a predetermined ratio or more in the one direction, or where the first overlapping surface and the second overlapping surface overlap each other at a predetermined ratio or more. A screw removal device may be provided that is placed in a second rotational position where they overlap each other by a smaller ratio, and wherein the first overlapping surface and the second overlapping surface are inclined with respect to an imaginary surface perpendicular to the one direction.

In addition, the cross-section of the first groove insertion portion, which is a cross-section of the first groove insertion portion perpendicular to the longitudinal direction of the first groove insertion portion, has a polygonal shape with the longest side formed by the intersection of the first overlapping surfaces, The cross section of the second groove insertion portion, which is a cross section of the second groove insertion portion perpendicular to the longitudinal direction of the second groove insertion portion, has a polygonal shape with the longest side formed by intersecting the second overlapping surface. can be provided.

Additionally, a screw removal device may be provided in which the cross-section of the first groove insertion portion and the cross-section of the second groove insertion portion each have a trapezoidal shape.

In addition, when the first body member and the second body member are rotated relative to each other in the first rotational position, the cross section of the first groove insertion portion and the cross section of the second groove insertion portion form a hexagonal shape. A removal device may be provided.

Additionally, a screw removal device may be provided in which a plurality of first overlapping surfaces and a plurality of second overlapping surfaces are provided.

In addition, at least one of the plurality of first overlapping surfaces is inclined in a different direction with respect to the other first overlapping surfaces and the virtual surface, and at least one of the plurality of second overlapping surfaces is inclined in a different direction with respect to the other first overlapping surfaces and the virtual surface. A screw removal device can be provided, inclined in different directions with respect to the virtual plane.

In addition, the plurality of first overlapping surfaces intersect with the cross-section of the first groove insertion portion, which is a cross-section of the first groove insertion portion perpendicular to the longitudinal direction of the first groove insertion portion, to form zigzag-shaped sides, and the plurality of A screw removal device may be provided in which the second overlapping surface intersects the transverse section of the second groove insertion portion, which is a cross section of the second groove insertion portion perpendicular to the longitudinal direction of the second groove insertion portion, forming a zigzag-shaped side. .

In addition, the cross-section of the first groove insertion portion has a polygonal shape including zigzag-shaped sides formed by the intersection of the first overlapping planes, and the cross-section of the second groove insertion portion is formed by the intersection of the second overlapping planes. A screw removal device may be provided having a polygonal shape including zigzag shaped sides.

In addition, when the first body member and the second body member are rotated relative to each other in the first rotational position, the cross section of the first groove insertion portion and the cross section of the second groove insertion portion form a hexagonal shape. A removal device may be provided.

In addition, the first body member further includes a first intermediate portion connected to the first groove insertion portion, and a first grip portion connected to the first intermediate portion, and the second body member includes the first intermediate portion. 2. A screw removal device may be provided, further comprising a second intermediate portion connected to the groove insertion portion, and a second grip portion connected to the second intermediate portion.

In addition, the first intermediate portion is connected to the first intermediate body portion in an inclined direction away from the first intermediate body portion and the second body member connected to the first groove insertion portion, and the first intermediate body portion is connected to the first gripper portion. It includes an inclined connection part, wherein the second intermediate part is connected to the second intermediate body part and inclined in a direction away from the first body member and a second intermediate body part connected to the second groove insertion part, and the second holding part is connected to the second intermediate body part. A screw removal device may be provided, comprising a second inclined connection portion being connected.

In addition, the first intermediate body portion includes a first overlapping guide surface extending in the longitudinal direction of the first intermediate body portion and inclined with respect to the virtual plane, and a first overlapping guide surface extending in the longitudinal direction of the first intermediate body portion and parallel to the virtual plane. One first rotation guide surface is formed, and the second intermediate body portion includes a second overlapping guide surface extending in the longitudinal direction of the second intermediate body portion and inclined with respect to the virtual surface and the longitudinal direction of the second intermediate body portion. A screw removal device may be provided in which a second rotation guide surface extending from and parallel to the virtual plane is formed, respectively.

In addition, the first middle portion and the second middle portion each penetrate the first body member and the second body member to be rotatable with respect to each other, and further include a rotation shaft member extending in the one direction. A device may be provided.

In addition, the rotating shaft member is provided with a screw removal device that penetrates the first intermediate portion and the second intermediate portion at a position where the distance to the first and second groove insertion portions is smaller than the distance to the first and second gripping portions. It can be.

According to embodiments of the present invention, when removing a screw, the adhesive force with the insertion groove formed on the screw head is increased to remove the screw from the screw coupling member to which the screw is coupled without damaging the insertion groove, and the insertion groove is already damaged. Even if it is, there is an effect that the screw can be easily removed from the screw coupling member.

1 is a perspective view showing the first body member and the second body member of the screw removal device according to the first embodiment of the present invention when rotated relative to each other in the first rotation position, and the first groove insertion portion and the second groove This is an enlarged view and cross-sectional view of the insertion part.
Figure 2 is an exploded perspective view of the screw removal device according to the first embodiment of the present invention and an enlarged view of the first groove insertion portion and the second groove insertion portion.
Figure 3 is a perspective view showing the first body member and the second body member of the screw removal device according to the first embodiment of the present invention when rotated relative to each other in the second rotation position, and the first groove insertion portion and the second groove This is an enlarged view and cross-sectional view of the insertion part.
Figure 4 is a state diagram of the screw removal device according to the first embodiment of the present invention, showing the screw removal device being moved to a place where the screw is coupled to the screw coupling member.
Figure 5 is a diagram showing a state of use of the screw removal device according to the first embodiment of the present invention, in which the first body member and the second body member of the screw removal device are rotated to the first rotation position, and the first body member is rotated to the first rotation position. This is a diagram showing the groove insertion portion and the second groove insertion portion of the second body member being inserted into the insertion groove of the screw.
Figure 6 is a diagram showing a state of use of the screw removal device according to the first embodiment of the present invention, in a state where the first groove insertion portion of the first body member and the second groove insertion portion of the second body member are inserted into the insertion groove of the screw. , the first body member and the second body member of the screw removal device are rotated to the second rotational position, so that at least a portion of the first groove insertion portion and at least a portion of the second groove insertion portion are in close contact with at least a portion of the insertion groove of the screw. This is a drawing showing what was done.
7 is a diagram illustrating a state of use of the screw removal device according to the first embodiment of the present invention, in which at least a portion of the first groove insertion portion and at least a portion of the second groove insertion portion are in close contact with at least a portion of the insertion groove of the screw, This diagram shows that the screw is removed from the screw coupling member by rotating the removal device in the direction in which the screw is loosened.
Figure 8 is a perspective view showing the first body member and the second body member of the screw removal device according to the second embodiment of the present invention when rotated relative to each other in the first rotation position, the first groove insertion portion, and the second groove. This is an enlarged view and cross-sectional view of the insertion part.
Figure 9 is an exploded perspective view of the screw removal device according to the second embodiment of the present invention and an enlarged view of the first groove insertion portion and the second groove insertion portion.
Figure 10 is a perspective view showing the first body member and the second body member of the screw removal device according to the second embodiment of the present invention when rotated relative to each other in the second rotation position, the first groove insertion portion, and the second groove This is an enlarged view and cross-sectional view of the insertion part.
Figure 11 shows the first groove insertion portion and the second body member of the first body member in a state in which the first body member and the second body member of the screw removal device according to the second embodiment of the present invention are rotated to the first rotation position. This is a diagram showing that the second groove insertion part of is inserted into the insertion groove of the screw.
Figure 12 shows the screw removal device according to the second embodiment of the present invention in a state where the first groove insertion portion of the first body member and the second groove insertion portion of the second body member are inserted into the insertion groove of the screw. A diagram showing that the first body member and the second body member are rotated to the second rotation position so that at least a portion of the first groove insertion portion and at least a portion of the second groove insertion portion are brought into close contact with at least a portion of the insertion groove of the screw. am.

Hereinafter, specific embodiments for implementing the technical idea of the present invention will be described in detail with reference to the drawings.

In addition, when describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

Additionally, when a component is mentioned as being 'connected' to another component, it should be understood that it may be directly connected to the other component, but that other components may exist in between.

The terms used in this specification are merely used to describe specific embodiments and are not intended to limit the invention. Singular expressions include plural expressions unless the context clearly dictates otherwise.

In addition, it should be noted in advance that the expression of direction in this specification is explained based on the drawings, and may be expressed differently if the direction of the object in question changes. For the same reason, in the accompanying drawings, some components are exaggerated, omitted, or schematically shown, and the size of each component does not entirely reflect the actual size.

Additionally, terms including ordinal numbers, such as first, second, etc., may be used to describe various components, but the components are not limited by these terms. These terms are used only to distinguish one component from another.

As used in the specification, the meaning of "comprising" is to specify a specific characteristic, area, integer, step, operation, element and/or component, and to specify another specific property, area, integer, step, operation, element, component and/or group. It does not exclude the existence or addition of .

Hereinafter, the specific configuration of the screw removal device according to the first embodiment of the present invention will be described with reference to FIGS. 1 to 3. The screw removal device (1) according to the first embodiment of the present invention is a device that removes the screw (2) from the screw coupling member (3) to which the screw (2) is coupled. The screw (2) removed by the screw removal device (1) is connected to the screw body (2-1) on which screw threads (2-11) are formed on at least part of the outer circumference and the upper part of the screw body (2-1) and is connected to the insertion groove. It may include a screw head (2-2) formed with (2-21). The screw removal device 1 has a scissor shape and is rotated together with the screw 2 so that the screw 2 is released from the screw engaging member 3, so that the screw 2 can be removed from the screw engaging member 3. . This screw removal device 1 may include a first body member 100, a second body member 200, and a rotating shaft member 300.

Referring to FIGS. 1 to 3 , the first body member 100 and the second body member 200 may be connected through a rotation axis member 300 to rotate with respect to each other. The first body member 100 and the second body member 200 may be rotated relative to each other to be placed in the first rotational position or the second rotational position. Here, the first rotation position is a position where a first groove insertion portion 110 to be described later and a second groove insertion portion 210 to be described later overlap by a predetermined ratio or more in one direction where the rotation shaft member 300 extends, and the second The rotation position may be a position where the first groove insertion portion 110 and the second groove insertion portion 210 overlap by less than a predetermined ratio in one direction in which the rotation shaft member 300 extends. Additionally, at the first rotation position, the overlap ratio of the first groove insertion portion 110 and the second groove insertion portion 210 in one direction in which the rotation shaft member 300 extends may be maximized. Additionally, in this specification, one direction in which the rotating shaft member 300 extends may be the thickness direction of the first body member 100 and the second body member 200 and may be referred to as the axial extension direction. The first body member 100 may include a first groove insertion part 110, a first middle part 120, and a first gripping part 130.

Referring to FIG. 1, the first groove insertion portion 110 has a predetermined ratio in one direction in which the rotation axis member 300 extends at the first rotation position of the first body member 100 and the second body member 200. As described above, they may overlap with the second groove insertion portion 210. The first groove insertion portion 110 is such that the second groove insertion portion 210 and the rotation axis member 300 extend at the first rotation position of the first body member 100 and the second body member 200. They can overlap each other by more than 95% in one direction. In addition, the first groove insertion portion 110 inserts the screw 2 together with the second groove insertion portion 210 at the first rotational position of the first body member 100 and the second body member 200. It can be inserted into the groove (2-21).

Referring to FIG. 3, the first groove insertion portion 110 has a predetermined ratio in one direction in which the rotation axis member 300 extends at the second rotation position of the first body member 100 and the second body member 200. They may overlap with the second groove insertion portion 210 at a smaller ratio. The first groove insertion portion 110 is such that the second groove insertion portion 210 and the rotation axis member 300 extend at the second rotation position of the first body member 100 and the second body member 200. They can overlap each other by less than 95% in one direction. In addition, at least a part of the first groove insertion part 110 is together with at least a part of the second groove insertion part 210 in the second rotation position of the first body member 100 and the second body member 200. , may be in close contact with at least a portion of the insertion groove (2-21) of the screw (2).

A first overlapping surface 111 may be formed in the first groove insertion portion 110. The first overlapping surface 111 may overlap a second overlapping surface 211 formed in the second groove insertion portion 210, which will be described later, in one direction in which the rotation axis member 300 extends. The first overlapping surface 111 is a second overlapping surface ( 211) and may overlap with each other. The first overlapping surface 111 extends in one direction where the second overlapping surface 211 and the rotation axis member 300 extend from the first rotational position of the first body member 100 and the second body member 200. They can overlap each other by more than 95%. The first overlapping surface 111 is overlapped at a second rotational position of the first body member 100 and the second body member 200 at a ratio smaller than a predetermined ratio in one direction in which the rotation axis member 300 extends. They may overlap with the surface 211. The first overlapping surface 111 extends in one direction where the second overlapping surface 211 and the rotation axis member 300 extend at the second rotation position of the first body member 100 and the second body member 200. They can overlap each other by less than 95%.

The first overlapping surface 111 may be formed to extend in the longitudinal direction of the first groove insertion portion 110. Additionally, the first overlapping surface 111 may be inclined with respect to the virtual surface VF perpendicular to one direction in which the rotation axis member 300 extends. For example, the first overlapping surface 111 may be inclined at 60 degrees with respect to the virtual surface VF perpendicular to one direction in which the rotation axis member 300 extends.

The first groove insertion portion 110 is inserted into the insertion groove 2-21 of the screw 2 together with the second groove insertion portion 210 of the second body member 200 and is inserted into the insertion groove 2-21. In order to be in close contact, it may have a shape that partially corresponds to the shape of the insertion groove 2-21 of the screw 2. For example, when the insertion groove 2-21 of the screw 2 has a polygonal shape, the cross section of the first groove insertion portion 110 is a cross section cut perpendicular to the longitudinal direction of the first groove insertion portion 110. may have a polygonal shape in which the side opposite to the second groove insertion portion 210 is formed to be the longest. In other words, when the insertion groove 2-21 of the screw 2 has a polygonal shape, the cross section of the first groove insertion portion 110 has the longest side formed by the intersection of the first overlapping surface 111. It may have a polygonal shape. As a more detailed example, when the insertion groove 2-21 of the screw 2 has a hexagonal shape, the cross section of the first groove insertion portion 110 may have a trapezoidal shape. In addition, the cross section of the first groove insertion portion 110 is, when the first body member 100 and the second body member 200 are rotated relative to each other to the first rotation position, the second groove insertion portion 210 It can form a hexagonal shape with a cross section of.

The first middle part 120 may be connected to the first groove insertion part 110. The first middle part 120 may be integrated with the first groove insertion part 110 and connected to the first groove insertion part 110. The first middle portion 120 may include a first middle body portion 121 and a first inclined connection portion 122.

The first intermediate body portion 121 may be connected to the first groove insertion portion 110. The first intermediate body portion 121 may be integrated with the first groove insertion portion 110 and connected to the first groove insertion portion 110. The first intermediate body portion 121 may be connected to the first groove insertion portion 110 so as to extend in the longitudinal direction of the first groove insertion portion 110. A first axis through-hole 121-1, a first overlapping guide surface 121-2, and a first rotation guide surface 121-3 may be formed in the first intermediate body portion 121.

The rotating shaft member 300 may penetrate the first shaft through hole 121-1. The first overlapping guide surface 121-2 extends in the longitudinal direction of the first intermediate body portion 121 and may be inclined with respect to a virtual plane VF perpendicular to one direction in which the rotation axis member 300 extends. For example, the first overlapping guide surface 121-2 may be inclined at 60 degrees with respect to the virtual surface VF perpendicular to one direction in which the rotation axis member 300 extends. The first rotation guide surface 121-3 extends in the longitudinal direction of the first intermediate body portion 121 and may be parallel to a virtual plane VF perpendicular to one direction in which the rotation axis member 300 extends. Additionally, the first rotation guide surface 121-3 may extend as part of the first inclined connection portion 122.

The first inclined connection part 122 may be connected to the first intermediate body part 121 at an angle in a direction away from the second body member 200. The first inclined connection portion 122 may be integrated with the first intermediate body portion 121 and connected to the first intermediate body portion 121.

The first gripping part 130 may be connected to the first middle part 120. The first gripping part 130 may be connected to the first inclined connection part 122 of the first middle part 120. The first gripping portion 130 may be integrated with the first inclined connecting portion 122 of the first middle portion 120 and connected to the first inclined connecting portion 122.

Referring to FIGS. 1 to 3 , the second body member 200 may be rotatably connected to the first body member 100 around a rotation center extending in one direction. The center of rotation may be the rotation axis member 300, and the second body member 200 may be connected to the first body member 100 through the rotation axis member 300 so that it rotates with respect to the first body member 100. . The second body member 200 may include a second groove insertion part 210, a second middle part 220, and a second gripping part 230.

Referring to FIG. 1, the second groove insertion portion 210 inserts the first groove of the first body member 100 at the first rotational position of the first body member 100 and the second body member 200. The portion 110 and the rotating shaft member 300 may overlap each other by a predetermined ratio or more in one direction in which they extend. The second groove insertion portion 210 is such that the first groove insertion portion 110 and the rotation axis member 300 extend at the first rotation position of the first body member 100 and the second body member 200. They can overlap each other by more than 95% in one direction. In addition, the second groove insertion portion 210 inserts the screw 2 together with the first groove insertion portion 110 at the first rotational position of the first body member 100 and the second body member 200. It can be inserted into the groove (2-21).

Referring to FIG. 3, the second groove insertion portion 210 has a predetermined ratio in one direction in which the rotation axis member 300 extends at the second rotation position of the first body member 100 and the second body member 200. They may overlap with the first groove insertion portion 110 at a smaller ratio. The second groove insertion portion 210 is such that the first groove insertion portion 110 and the rotation axis member 300 extend at the second rotation position of the first body member 100 and the second body member 200. They can overlap each other by less than 95% in one direction. In addition, at least a part of the second groove insertion part 210 is together with at least a part of the first groove insertion part 110 in the second rotation position of the first body member 100 and the second body member 200. , may be in close contact with at least a portion of the insertion groove (2-21) of the screw (2).

A second overlapping surface 211 may be formed in the second groove insertion portion 210. The second overlapping surface 211 may face the first overlapping surface 111 of the first groove insertion part 110. The second overlapping surface 211 may overlap the first overlapping surface 111 of the first groove insertion part 110 in one direction in which the rotation axis member 300 extends. The second overlapping surface 211 is a first overlapping surface ( 111) and may overlap with each other. The second overlapping surface 211 extends in one direction where the first overlapping surface 111 and the rotation axis member 300 extend at the first rotational position of the first body member 100 and the second body member 200. They can overlap each other by more than 95%. The second overlapping surface 211 overlaps the first body member 100 and the second body member 200 at a ratio smaller than a predetermined ratio in one direction in which the rotation axis member 300 extends at the second rotation position of the first body member 100 and the second body member 200. They may overlap with the surface 111. The second overlapping surface 211 extends in one direction where the first overlapping surface 111 and the rotation axis member 300 extend at the second rotation position of the first body member 100 and the second body member 200. They can overlap each other by less than 95%.

The second overlapping surface 211 may be formed to extend in the longitudinal direction of the second groove insertion portion 210. Additionally, the second overlapping surface 211 may be inclined with respect to the virtual surface VF perpendicular to one direction in which the rotation axis member 300 extends. For example, the second overlapping surface 211 may be inclined at 60 degrees with respect to the virtual surface VF perpendicular to one direction in which the rotation axis member 300 extends.

The second groove insertion portion 210 is inserted into the insertion groove 2-21 of the screw 2 together with the first groove insertion portion 110 of the first body member 100 and is inserted into the insertion groove 2-21. In order to be in close contact, the insertion groove 2-21 of the screw 2 may have a shape corresponding to another part of the shape. For example, when the insertion groove 2-21 of the screw 2 has a polygonal shape, the cross section of the second groove insertion portion 210 is a cross section cut perpendicular to the longitudinal direction of the second groove insertion portion 210. may have a polygonal shape in which the side opposite to the first groove insertion portion 110 is formed with the longest side. When the insertion groove 2-21 of the screw 2 has a polygonal shape, the cross section of the second groove insertion portion 210 may have a polygonal shape with the longest side formed by the second overlapping surface 211. there is. As a more detailed example, when the insertion groove 2-21 of the screw 2 has a hexagonal shape, the cross section of the second groove insertion portion 210 may have a trapezoidal shape. In addition, the cross section of the second groove insertion portion 210 is, when the first body member 100 and the second body member 200 are rotated relative to each other to the first rotation position, the first groove insertion portion 110 It can form a hexagonal shape with a cross section of.

The second middle part 220 may be connected to the second groove insertion part 210. The second middle part 220 may be integrated with the second groove insertion part 210 and connected to the second groove insertion part 210. The second middle portion 220 may include a second middle body portion 221 and a second inclined connection portion 222.

The second intermediate body portion 221 may be connected to the second groove insertion portion 210. The second intermediate body portion 221 may be integrated with the second groove insertion portion 210 and connected to the second groove insertion portion 210. The second intermediate body portion 221 may be connected to the second groove insertion portion 210 so as to extend in the longitudinal direction of the second groove insertion portion 210. A second axis through-hole 221-1, a second overlapping guide surface 221-2, and a second rotation guide surface 221-3 may be formed in the second intermediate body portion 221.

The rotating shaft member 300 may penetrate the second shaft through hole 221-1. The second overlapping guide surface 221-2 extends in the longitudinal direction of the second intermediate body portion 221 and may be inclined with respect to a virtual plane VF perpendicular to one direction in which the rotation axis member 300 extends. For example, the second overlapping guide surface 221-2 may be inclined at 60 degrees with respect to the virtual surface VF perpendicular to one direction in which the rotation axis member 300 extends. The second rotation guide surface 221-3 extends in the longitudinal direction of the second intermediate body portion 221 and may be parallel to a virtual plane VF perpendicular to one direction in which the rotation axis member 300 extends. The second rotation guide surface 221-3 may extend as part of the second inclined connection portion 222.

The second inclined connection part 222 may be connected to the second intermediate body part 221 at an angle in a direction away from the first body member 100. The second inclined connection portion 222 may be integrated with the second intermediate body portion 221 and connected to the second intermediate body portion 221.

The second gripping part 230 may be connected to the second middle part 220. The second gripping part 230 may be connected to the second inclined connection part 222 of the second middle part 220. The second gripping portion 230 may be integrated with the second inclined connecting portion 222 of the second middle portion 220 and connected to the second inclined connecting portion 222.

The rotating shaft member 300 may connect the first body member 100 and the second body member 200 to be rotatable with respect to each other. The rotating shaft member 300 extends in one direction and may penetrate the first middle portion 120 of the first body member 100 and the second middle portion 220 of the second body member 200, respectively. The rotating shaft member 300 extends in one direction and may penetrate the first intermediate body portion 121 of the first intermediate portion 120 and the second intermediate body portion 221 of the second intermediate portion 220, respectively. The rotating shaft member 300 may penetrate the first shaft through hole 121-1 of the first intermediate body portion 121 and the second shaft through hole 221-1 of the second intermediate body portion 221, respectively. there is.

The rotating shaft member 300 is connected to the first intermediate portion 120 and the second portion at a position where the distance to the first and second groove insertion portions 110 and 210 is smaller than the distance to the first and second gripping portions 130 and 230. It may penetrate the middle portion 220. In other words, the rotating shaft member 300 is biased toward the first and second groove insertion portions 110 and 210 and may penetrate the first middle portion 120 and the second middle portion 220, respectively. The rotating shaft member 300 has a first intermediate body portion 121 and a second body portion such that the distance to the first and second groove insertion portions 110 and 210 is smaller than the distance to the first and second inclined connecting portions 122 and 222. Each can penetrate the middle body portion 221. In other words, the rotating shaft member 300 is biased toward the first and second groove insertion portions 110 and 210 and may penetrate the first intermediate body portion 121 and the second intermediate body portion 221, respectively. Due to the arrangement of the rotation axis member 300, the first groove insertion portion 110 and the second groove insertion portion 210 are formed by rotation of the first body member 100 and the second body member 200 with respect to each other. A relatively large force can act on it. In addition, the adhesion force of each of the first groove insertion portion 110 and the second groove insertion portion 210 to the insertion groove 2-21 of the screw 2 may be relatively large. The rotating shaft member 300 may include a shaft portion 310, a first engaging portion 320, and a second engaging portion 330.

The shaft portion 310 may penetrate the first middle portion 120 of the first body member 100 and the second middle portion 220 of the second body member 200, respectively. The shaft portion 310 may penetrate the first intermediate body portion 121 of the first intermediate portion 120 and the second intermediate body portion 221 of the second intermediate portion 220, respectively. The shaft portion 310 may penetrate the first shaft through hole 121-1 of the first intermediate body portion 121 and the second shaft through hole 221-1 of the second intermediate body portion 221, respectively. . The shaft portion 310 may extend in one direction. The shaft portion 310 may extend in one direction in which the rotating shaft member 300 extends.

The first engaging portion 320 may be connected to one side of the shaft portion 310 so that the second middle portion 220 of the second body member 200 is caught. The first engaging portion 320 may be connected to one side of the shaft portion 310 so that the second intermediate body portion 221 of the second intermediate portion 220 is caught. The first engaging portion 320 may be integrated with the shaft portion 310 and connected to one side of the shaft portion 310.

The second locking portion 330 may be connected to the other side of the shaft portion 310 so that the first middle portion 120 of the first body member 100 is caught. A shaft connection hole 331 is formed in the second locking portion 330, and the other side of the shaft portion 310 is inserted into the shaft connecting hole 331, so that the second locking portion 330 can be connected to the other side of the shaft portion 310. there is.

Hereinafter, with reference to FIGS. 4 to 7, the operation and effect of the screw removal device 1 according to the first embodiment of the present invention having the above-described configuration will be described.

Referring to FIG. 4, the user can move the screw removal device 1 to a location where the screw 2 to be removed is coupled to the screw engaging member 3.

Referring to FIG. 5, after moving the screw removal device (1) to a location where the screw (2) to be removed is coupled to the screw engaging member (3), the user removes the first body member (100) of the screw removal device (1). ) and the gripping part 230 of the second body member 200 can be gripped. In addition, the user holds the gripping portion 130 of the first body member 100 and the gripping portion 230 of the second body member 200, and holds the first body member 100 and the second body member 200. (200) can be rotated relative to each other in the first rotation position. When the first body member 100 and the second body member 200 are rotated relative to each other to the first rotational position, the first overlapping surface 111 of the first groove insertion portion 110 of the first body member 100 ) and the second overlapping surface 211 of the second groove insertion portion 210 of the second body member 200 may overlap each other by more than 95% in one direction in which the rotating shaft member 300 extends. In this state, the user inserts the first groove insertion portion 110 of the first body member 100 and the second groove insertion portion 210 of the second body member 200 together into the insertion groove 2 of the screw 2. -21).

Referring to FIG. 6, the first groove insertion portion 110 of the first body member 100 and the second groove insertion portion 210 of the second body member 200 are inserted into the insertion groove 2 of the screw 2 together. -21), the user can rotate the first body member 100 and the second body member 200 relative to each other to the second rotation position. When the first body member 100 and the second body member 200 are rotated relative to each other to the second rotation position, the first overlapping surface 111 of the first groove insertion portion 110 of the first body member 100 ) and the second overlapping surface 211 of the second groove insertion portion 210 of the second body member 200 may overlap each other by less than 95% in one direction in which the rotating shaft member 300 extends. In other words, when the first body member 100 and the second body member 200 are rotated relative to each other in the second rotation position, the first groove insertion portion 110 and the second groove insertion portion 210 are spaced apart from each other. You can lose.

Insertion of the first groove insertion portion 110 of the first body member 100 and the second groove of the second body member 200 in the second rotation position of the first body member 100 and the second body member 200. When the parts 210 move away from each other, at least a portion of the first groove insertion portion 110 of the first body member 100 and at least a portion of the second groove insertion portion 210 of the second body member 200 are screwed. It may be in close contact with at least a portion of the insertion groove (2-21) of (2).

Referring to FIG. 7, at least a portion of the first groove insertion portion 110 of the first body member 100 and at least a portion of the second groove insertion portion 210 of the second body member 200 are screws 2. While in close contact with at least a portion of the insertion groove 2-21, the user can rotate the screw removal device 1 in the direction in which the screw 2 is loosened. By rotating the screw removal device (1) in the direction in which the screw (2) is loosened, the screw (2) is released from the screw engaging member (3), thereby allowing the screw (2) to be removed from the screw engaging member (3). You can.

In this way, the screw removal device 1 according to the first embodiment of the present invention can increase the adhesion force with the insertion groove 2-21 of the screw 2 when removing the screw 2. Therefore, the screw (2) can be removed from the screw coupling member (3) without damaging the insertion groove (2-21), and the screw (2) can be easily screwed together even if the insertion groove (2-21) has already been damaged. It can be removed from member (3).

Meanwhile, in addition to this configuration, according to the second embodiment of the present invention, the first overlapping surface 111 of the first groove insertion part 110 and the second overlapping surface 211 of the second groove insertion part 210 are Each may be provided in plural pieces.

Hereinafter, the second embodiment will be described with reference to FIGS. 8 to 12. In describing the second embodiment of the present invention, when compared to the above-described first embodiment, the first overlapping surface 111 of the first groove insertion portion 110 and the second groove insertion portion 210 There is a difference in that a plurality of two overlapping surfaces 211 are provided, and this difference will be mainly explained, and the same description and reference numerals will be used in the above-described embodiments.

Referring to FIGS. 8 to 10, the first overlapping surface 111 of the first groove insertion part 110 and the second overlapping surface 211 of the second groove insertion part 210 may be provided in plural numbers. . For example, there may be three first and second overlapping surfaces 111 and 211, respectively.

One or more of the plurality of first overlapping surfaces 111 may be inclined in different directions with respect to the other first overlapping surfaces 111 and the virtual surface VF perpendicular to one direction in which the rotation axis member 300 extends. For example, two of the three first overlapping surfaces 111 may be inclined to one side of the virtual surface VF perpendicular to one direction in which the rotation axis member 300 extends. Additionally, one of the three first overlapping surfaces 111 may be inclined to the other side of the virtual surface VF perpendicular to one direction in which the rotation axis member 300 extends.

The plurality of first overlapping surfaces 111 may form zigzag-shaped sides by intersecting the cross section of the first groove insertion portion 110, which is a cross section cut perpendicular to the longitudinal direction of the first groove insertion portion 110. . In other words, the first overlapping surfaces 111 inclined in different directions may be alternately connected to the virtual surface VF perpendicular to one direction in which the rotating shaft member 300 extends.

The cross-section of the first groove insertion portion 110 may have a polygonal shape including zigzag-shaped sides formed by the intersection of the first overlapping surfaces 111. In addition, when the first body member 100 and the second body member 200 are rotated relative to each other to the first rotational position, the cross section of the first groove insertion portion 110 and the cross section of the second groove insertion portion 210 The cross-section may form a hexagonal shape.

One or more of the plurality of second overlapping surfaces 211 may be inclined in different directions with respect to the other second overlapping surfaces 211 and the virtual surface VF perpendicular to one direction in which the rotation axis member 300 extends. For example, two of the three second overlapping surfaces 211 may be inclined to one side of the virtual surface VF perpendicular to one direction in which the rotation axis member 300 extends. Additionally, one of the three second overlapping surfaces 211 may be inclined to the other side of the virtual surface VF perpendicular to one direction in which the rotation axis member 300 extends.

The plurality of second overlapping surfaces 211 may form zigzag-shaped sides by intersecting the cross section of the second groove insertion portion 210, which is a cross section cut perpendicular to the longitudinal direction of the second groove insertion portion 210. . In other words, the second overlapping surfaces 211 inclined in different directions may be alternately connected to the virtual surface VF perpendicular to one direction in which the rotating shaft member 300 extends.

The cross section of the second groove insertion portion 210 may have a polygonal shape including zigzag-shaped sides formed by the intersection of the second overlapping surfaces 211. In addition, when the first body member 100 and the second body member 200 are rotated relative to each other to the first rotational position, the cross section of the second groove insertion portion 210 and the cross section of the first groove insertion portion 110 The cross-section may form a hexagonal shape.

Referring to FIG. 11, at the first rotational position of the first body member 100 and the second body member 200, a plurality of first overlapping surfaces 111 of the first body member 100 and the second body member The plurality of second overlapping surfaces 211 of 200 may overlap each other by more than 95% in one direction in which the rotating shaft member 300 extends. In this state, the user inserts the first groove insertion portion 110 of the first body member 100 and the second groove insertion portion 210 of the second body member 200 together into the insertion groove 2 of the screw 2. -21).

Referring to FIG. 12, in the second rotation position of the first body member 100 and the second body member 200, the plurality of first overlapping surfaces 111 of the first body member 100 and the second body member The plurality of second overlapping surfaces 211 of 200 may overlap each other by less than 95% in one direction in which the rotating shaft member 300 extends. In addition, at least a portion of the first groove insertion portion 110 of the first body member 100 and at least a portion of the second groove insertion portion 210 of the second body member 200 are inserted into the insertion groove of the screw 2. It may be in close contact with at least part of 2-21).

As described above, the plurality of first overlapping surfaces 111 intersect the cross section of the first groove insertion portion 110, which is a cross section cut perpendicular to the longitudinal direction of the first groove insertion portion 110, and form a zigzag-shaped edge. can be formed. In addition, the plurality of second overlapping surfaces 211 intersect the transverse cross section of the second groove insertion portion 210, which is a cross section cut perpendicular to the longitudinal direction of the second groove insertion portion 210, to form zigzag-shaped sides. You can. In addition, when the first body member 100 and the second body member 200 are moved from the first rotational position to the second rotational position, the first groove insertion portion 110 and the second groove insertion portion 210 When viewed in cross section, it can be moved to spread not only up and down but also left and right. In other words, referring to FIGS. 8 to 12, among the three first overlapping surfaces 111 and three second overlapping surfaces 211, the first overlapping surface 111 and the second overlapping surface 211 have different inclination directions. ), the first groove insertion portion 110 and the second groove insertion portion 210 can be moved so that they spread apart not only in the vertical direction but also in the left and right directions when viewed in cross section. Therefore, the size of the portion of the first groove insertion portion 110 and the portion of the second groove insertion portion 210 that are in close contact with the insertion groove 2-21 of the screw 2 may be relatively large, and the adhesion force may also be large. .

At least a portion of the first groove insertion portion 110 of the first body member 100 and at least a portion of the second groove insertion portion 210 of the second body member 200 are inserted into the insertion groove 2 of the screw 2. While in close contact with at least a portion of 21), the user can rotate the screw removal device 1 in the direction in which the screw 2 is loosened. By rotating the screw removal device (1) in the direction in which the screw (2) is loosened, the screw (2) is released from the screw engaging member (3), thereby allowing the screw (2) to be removed from the screw engaging member (3). You can. As described above, the portion of the first groove insertion portion 110 and the portion of the second groove insertion portion 210 that are in close contact with the insertion groove 2-21 of the screw 2 are relatively large in size and the adhesion force is also large. , removal of the screw 2 may be easy.

Although embodiments of the present invention have been described above as specific embodiments, this is merely an example, and the present invention is not limited thereto, and should be construed as having the widest scope following the technical idea disclosed in this specification. A person skilled in the art may implement a pattern of a shape not specified by combining/substituting the disclosed embodiments, but this also does not depart from the scope of the present invention. In addition, a person skilled in the art can easily change or modify the embodiments disclosed based on the present specification, and it is clear that such changes or modifications also fall within the scope of the present invention.

1: Screw removal device 2: Screw
2-1: Screw body 2-11: Screw thread
2-2: Screw head 2-21: Insertion groove
3: Screw coupling member 100: First body member
110: first groove insertion part 111: first overlapping surface
120: first middle portion 121: first middle body portion
121-1: First axis through-hole 121-2: First overlapping guide surface
121-3: first rotation guide surface 122: first inclined connection part
130: first gripping part 200: second body member
210: second groove insertion part 211: second overlapping surface
220: second middle portion 221: second middle body portion
221-1: Second axis through-hole 221-2: Second overlapping guide surface
221-3: second rotation guide surface 222: second inclined connection part
230: second gripping part 300: rotating shaft member
310: shaft portion 320: first engaging portion
330: second engaging portion 331: shaft connection hole
VF: virtual plane

Claims (14)

A first body member including a first groove insertion portion;
It includes a second body member rotatably connected to the first body member around a rotation center that includes a second groove insertion portion and extends in one direction,
A first overlapping surface is formed in the first groove insertion part to extend in the longitudinal direction of the first groove insertion part, and in the second groove insertion part, a second overlapping surface faces the first overlapping surface and the second groove is formed in the first groove insertion part. It is formed to extend in the longitudinal direction of the insertion portion,
The first body member and the second body member,
A first rotation position in which the first overlapping surface and the second overlapping surface overlap each other by a predetermined ratio or more in the one direction, or a second rotation position where the first overlapping surface and the second overlapping surface overlap each other by a ratio smaller than the predetermined ratio. placed in a rotating position,
The first overlapping surface and the second overlapping surface are inclined with respect to a virtual surface perpendicular to the one direction,
The first overlapping surface and the second overlapping surface are each provided in plural numbers,
In the second rotation position, at least one of the plurality of first overlapping surfaces and at least one of the plurality of second overlapping surfaces are spaced apart from each other in a direction perpendicular to the direction in which the first overlapping surface and the second overlapping surface are inclined. configured to be,
Screw removal device. delete delete delete delete According to claim 1,
At least one of the plurality of first overlapping surfaces is inclined in a different direction with respect to the other first overlapping surfaces and the virtual surface,
At least one of the plurality of second overlapping surfaces is inclined in a different direction with respect to the other second overlapping surfaces and the virtual surface,
Screw removal device. According to claim 6,
The plurality of first overlapping surfaces intersect a cross section of the first groove insertion portion perpendicular to the longitudinal direction of the first groove insertion portion, forming zigzag-shaped sides,
The plurality of second overlapping surfaces intersect with the cross section of the second groove insertion portion, which is a cross section of the second groove insertion portion perpendicular to the longitudinal direction of the second groove insertion portion, forming zigzag-shaped sides,
Screw removal device. According to claim 7,
The cross-section of the first groove insertion portion has a polygonal shape including zigzag-shaped sides formed by intersection of the first overlapping surfaces,
The cross section of the second groove insertion portion has a polygonal shape including zigzag-shaped sides formed by intersection of the second overlapping surfaces,
Screw removal device. According to claim 8,
When the first body member and the second body member are rotated relative to each other to the first rotational position,
The cross section of the first groove insertion portion and the cross section of the second groove insertion portion form a hexagonal shape,
Screw removal device. According to claim 1,
The first body member further includes a first intermediate portion connected to the first groove insertion portion, and a first grip portion connected to the first intermediate portion,
The second body member further includes a second middle portion connected to the second groove insertion portion, and a second grip portion connected to the second middle portion,
Screw removal device. According to claim 10,
The first middle part
A first intermediate body portion connected to the first groove insertion portion and a first inclined connection portion connected to the first intermediate body portion inclined in a direction away from the second body member and to which the first grip portion is connected,
The second middle part is
A second intermediate body portion connected to the second groove insertion portion and a second inclined connection portion connected to the second intermediate body portion inclined in a direction away from the first body member and connected to the second grip portion,
Screw removal device. According to claim 11,
The first intermediate body portion includes a first overlapping guide surface extending in the longitudinal direction of the first intermediate body portion and inclined with respect to the virtual plane, and a first overlapping guide surface extending in the longitudinal direction of the first intermediate body portion and parallel to the virtual plane. 1 rotation guide surface is formed, respectively,
The second intermediate body includes a second overlapping guide surface extending in the longitudinal direction of the second intermediate body and inclined with respect to the virtual plane, and a second overlapping guide surface extending in the longitudinal direction of the second intermediate body and parallel to the virtual plane. Each rotation guide surface is formed,
Screw removal device. According to claim 10,
Further comprising a rotation shaft member extending in the one direction, which penetrates the first middle portion and the second middle portion to rotatably connect the first body member and the second body member with respect to each other,
Screw removal device. According to claim 13,
The rotating shaft member is
Penetrating the first middle portion and the second middle portion at a position where the distance to the first and second groove insertion portions is smaller than the distance to the first and second grip portions,
Screw removal device.

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