JP2022501205A - Fastener pull-out removal device - Google Patents

Abstract

The fastener pull-out removal tool device according to the present invention includes a torque tool main body, a plurality of engaging portions, and a release bolt. A plurality of engaging portions that grip the sides of the detached fastener are radially arranged around the axis of rotation of the torque tool body. The plurality of engaging portions are connected in the circumferential direction around the base of the torque tool main body, and defines the shape of the socket main body for removing the peeled fastener. A threaded opening is provided through the base so that the release bolt can be screw engaged into the threaded opening on the opposite side of the plurality of engagements. When the detached fastener is jammed inside the plurality of engagement portions, the release bolt can be screwed into the space between the plurality of engagement portions to remove the detached fastener from the torque tool body.

Description

The present invention generally relates to fasteners (fasteners), in particular various tools designed to pull out (remove) bolts and nuts, and more specifically to non-slip, designed to remove damaged fasteners. Disclosed is a removal tool for removing damaged fasteners from a combination of functional threaded extractors and a non-slip threaded extractor combination.

Threaded parts (fasteners) such as hex bolts, nuts, and screws are used to secure and hold multiple members by engaging complementary screws called female threads. Generally, these types of fasteners consist of an external thread and a cylindrical shaft with a head at one end. The external threads engage with the threads of the complementary female threads tapped on the holes or nuts to secure the fasteners in place and secure the associated members together. The head is a means for receiving a torque force from the outside and turning (driving) the fastener with respect to the female screw. The head is specially shaped so that an external tool such as a wrench can rotate the fastener and apply the appropriate torque to the fastener to engage the complementary female screw. This type of fastener is simple, very effective, inexpensive and widely used in modern construction.

One of the most common problems with using these types of fasteners, whether male or female, is that the external tool slips on the head portion. This is typically caused by wear or corrosion of fasteners or tools, excessive tightening, or damage to the head portion of the fastener. Various methods are used to remove fasteners, some of which are more destructive than others. If the head of the fastener is damaged, more destructive methods need to be taken to remove the stuck fastener. Fastener drilling out is a common method used by some users. This method works well in some scenarios, but there is a high risk of damaging the internal threads of the holes.

The present invention provides a fastener extraction / removal device (extractor) that substantially eliminates the possibility of slipping. In the present invention, a series of integrated splines that bite into the fastener head are used to enable efficient torque transmission between the extractor bit and the fastener head portion. Another common problem when using conventional fastener extractors is that the head or whole of the fastener may remain attached to the extractor, according to the invention of the present application. The removal tool allows easy removal of some or all of the remaining fasteners from the extractor.

It is a perspective view which shows the torque tool main body which concerns on this invention, a plurality of engaging parts and a release bolt. It is a top view which shows the lower surface of the torque tool main body and the attachment main body which concerns on this invention. It is a top view of the torque tool main body and a plurality of engaging portions according to the present invention (detailed portions are shown in FIG. 4). It is a detailed view which corresponds to the area A of FIG. 4 of the plurality of engaging parts which concerns on this invention. It is a side view of the torque tool main body which concerns on this invention (the sectional view is shown in FIG. 6). It is sectional drawing of the torque tool main body which concerns on this invention, along the line AA of FIG. It is a side view of the release bolt which concerns on this invention. It is sectional drawing of the torque tool main body, a plurality of engaging parts, and a release bolt which concerns on this invention. It is a top view of the torque tool main body and a plurality of engaging portions of the first alternative embodiment according to the present invention (detailed view shown in FIG. 10 is shown). It is a detailed view of the part A of FIG. 9 of the plurality of engaging portions according to the 1st alternative embodiment of the present invention (detailed view is shown in FIG. 11). It is a detailed view of the B portion of FIG. 10 of the plurality of engaging portions according to the first alternative embodiment of the present invention. It is a top view of the torque tool main body and a plurality of engaging parts which concerns on the 2nd alternative embodiment of this invention.

All drawings are intended to illustrate particular aspects of the invention of the present application and are not intended to limit the scope of the invention of the present application.

The present invention broadly relates to an extractor (drawing tool) and its accessories, and more specifically to a fastener extractor and a removal tool. It can be difficult to remove damaged fasteners from the extractor. The present invention aims to solve this problem by providing a release tool selectively incorporated into the extractor. In particular, the release tool is designed to assist the user in removing broken fastener fragments left on the extractor. Further, the invention of the present application is compatible with the fastener of the head design based on the male screw member. Fasteners with head designs based on male thread members are also called male fasteners (male threads) and use the outer side of the fastener head to engage tools for tightening or removal. Such fasteners include hexagon bolts and nuts. An example of a male fastener is a bolt with a hexagonal head. Further, the present invention can be applied to both clockwise and counterclockwise threads.

As shown in FIGS. 1 and 8, the present invention includes a torque tool body (1), a threaded opening (4), a plurality of engaging portions (5), and a release bolt (12). .. The torque tool body (1) is used by the plurality of engaging portions (5) as a physical structure for applying the corresponding force to the fastener head. In the case of a male fastener, the torque tool body (1) is a tube-shaped member similar to a wrench socket, which is sized to fit on the male fastener so as to engage. The length, width, and diameter of the torque tool body (1) may vary to fit male fasteners of different sizes. The plurality of engaging portions (5) play a role of preventing slippage when the fastener is pulled out, and are arranged radially around the rotation shaft (2) of the torque tool body (1) as shown in FIG. There is.

More specifically, the plurality of engaging portions (5) are connected circumferentially around the base portion (3) of the torque tool body (1) in order to grip the side surface of the fastener head. As a result, the plurality of engaging portions (5) facilitate the transmission of torque to the male fastener by preventing slippage between the torque tool body (1) and the fastener head. The threaded opening (4) penetrates the base (3) and functions as a mounting means for the release bolt (12). More specifically, the release bolt (12) is screw engaged with the threaded opening (4) and is located on the opposite side of the plurality of engaging portions (5). As a result, when the damaged or detached fastener gets stuck in the plurality of engagements (5) after removal, the release bolt (12) pushes the damaged or detached fastener out of the plurality of engagements (5). Can be (removed).

As shown in FIGS. 1 to 3, the torque tool body (1) extends outward from the cross section of the plurality of engaging portions (5). As a result, a structure like a wrench socket is obtained in which a plurality of engaging portions (5) are arranged around the rotation axis (2) on the inner peripheral surface of the torque tool main body (1).

Further, by connecting the wrench handle laterally outside the torque tool body (1), a wrench handle attachment can be obtained. For both the wrench socket and the wrench handle attachment, each of the multiple engagements (5) is extended along a specific length of the torque tool body (1), resulting in torque. Define an empty space within the tool body (1). This empty space functions as a cavity for receiving the fastener head so that the plurality of engaging portions (5) grip the side surface of the fastener head.

In conventional socket wrench designs, most of the torque is transmitted to the male fastener through the side corners of the fastener head. However, with the passage of time, the lateral corners deteriorate, and the torque transmission efficiency from the socket wrench to the fastener head decreases, resulting in slippage. In the present invention, this problem is solved by moving the torque transmission point to the side surface of the fastener head. This is achieved by using multiple engaging portions (5). Each of the plurality of engaging portions (5) is arranged so as to engage (“bite”) the plane of the side surface rather than the corners of the side surface of the fastener head. This allows an appropriate amount of torque to be transmitted to the fastener head and rotate, resulting in the removal of the broken or detached fastener.

3 and 4 show preferred embodiments of the present invention. Each cross section of the plurality of engaging portions (5) includes a first inclined portion (6), a curved portion (7), and a second inclined portion (8). More specifically, the first inclined portion (6) is connected to the end of the curved portion (7), the second inclined portion (8) is connected to the end of the curved portion (7), and the first inclined portion is connected. The portion (6) and the second inclined portion (8) are arranged so as to face each other with respect to the curved portion (7). As a result, the gripping edge is defined between the pair of engaging portions (5) or in one of the engaging portions (5), and the gripping edge is attached to the fastener head during removal of the damaged or detached fastener. It is possible to cut. The upper surface (32) of the torque tool main body (1) is arranged between the outer surface of the base portion (3) and the plurality of engaging portions (5), and is a flat surface. In addition, the edge between the top surface (32) of the base (3) and the plurality of engagements (5) is either a chamfered edge or curved towards a threaded opening (4). One of the edges. In the first inclined portion (6) and the second inclined portion (8), the first inclined portion (6) or the second inclined portion (8) has an acute angle with respect to the curved portion (7). As such, they may be on the same straight line with each other or may be concave.

Further, as shown in FIGS. 3 and 4, the plurality of engaging portions (5) of the preferred embodiment are arranged at equal intervals in the torque tool body (1) to form a complete enclosure. ing. The lengths of the first inclined portion (6), the curved portion (7), and the second inclined portion (8) may be changed. Similarly, the corresponding angles between the first sloping section (6), curved section (7), and second sloping section (8) may vary to create a sharper tooth-like shape. good. In order to form the enclosed shape, the plurality of engaging portions (5) are composed of an arbitrary engaging portion (10) and an adjacent engaging portion (11). Here, the arbitrary engaging portion (10) is defined as an arbitrary engaging portion in which the adjacent engaging portion (11) is an engaging portion directly beside the arbitrary engaging portion (10). More specifically, the first inclined portion (6) of any engaging portion (10) is connected to form an obtuse angle with the second inclined portion (8) of the adjacent engaging portion (11). .. In other words, the profile of the gripping edge is defined by orienting the first inclined portion (6) and the second inclined portion (8) arranged adjacent to each other so as to form an obtuse angle. As mentioned above, the invention of the present application can be designed to fit various fastener head designs. This is achieved by varying the number of multiple engagements (5) to accommodate different types of fastener head designs. The number of engagements (5) generally corresponds to the number of sides of the fastener head. For example, a pentagonal fastener head has five lateral sides. In order to remove the male fastener having the pentagonal head, the user must utilize the embodiment of the present invention which constitutes five engaging portions as a plurality of engaging portions (5). Preferably, the number of the plurality of engaging portions (5) in contact with the fastener head may be 18, 12, 6, or 4.

9 to 11 show a first alternative embodiment of the present invention. Each cross section of the plurality of engaging portions (5) includes a first inclined portion (6), a curved portion (7), and a second inclined portion (8). The second ramp (8) further includes a proximal portion (81) and a distal portion (82). More specifically, the first inclined portion (6) is connected to the end of the curved portion (7), and the proximal portion (81) of the second inclined portion (8) is the curved portion (7). It is connected to the end, and the proximal portion (81) of the first inclined portion (6) and the second inclined portion (8) is arranged so as to face each other with respect to the curved portion (7). .. The distal portion (82) of the second tilted portion (8) is connected to the end of the proximal portion (81) of the second tilted portion (8) and is located opposite the curved portion (7). As a result, the gripping edge is defined between the proximal portion (81) of the second tilted portion (8) and the distal portion (82) of the second tilted portion (8), and the gripping edge is damaged or damaged. It will be possible to cut into the fastener head when removing the peeled fastener. Further, the proximal portion (81) of the second inclined portion (8) and the distal portion (82) of the second inclined portion (8) are oriented so as to form an obtuse angle, forming a profile of the gripping edge. do.

As shown in FIGS. 9 to 11, the plurality of engaging portions (5) of the first alternative embodiment are arranged at equal intervals in the torque tool main body (1) to form a complete enclosing shape. .. The lengths of the first inclined portion (6), the curved portion (7), and the second inclined portion (8) may be changed. Similarly, the corresponding angles between the first slope (6), bend (7), and second slope (8) vary to form a sharper tooth-like shape. You may. The plurality of engaging portions (5) constituting the enclosed shape include an arbitrary engaging portion (10) and an adjacent engaging portion (11). The arbitrary engaging portion (10) is any engaging portion (5) in a plurality of engaging portions (5) such that the adjacent engaging portion (11) is an engaging portion immediately beside the arbitrary engaging portion (10). It is an engaging part. More specifically, the first inclined portion (6) of any engaging portion (10) is connected in a straight line with the distal portion (82) of the adjacent engaging portion (11) and is distal. The portion (82) and the proximal portion (81) are adjacent to each other so as to form an obtuse angle with respect to the adjacent engaging portion (11).

In one embodiment of the first alternative embodiment, the angle between the first tilted portion (6) and the distal portion (82) is between the distal portion (82) and the proximal portion (81). Equal to the angle of, the distal portion (82) is laterally located along the sides of the fastener head. In addition, the first ramp (6), distal (82), and proximal (81) define the trapezoidal shape.

FIG. 12 shows a second alternative embodiment of the present invention. Each cross section of the plurality of engaging portions (5) includes a first inclined portion (6), a curved portion (7), and a second inclined portion (8). The bend (7) further comprises a first section, a second section, a third section, and a fourth section. More specifically, the first section is connected adjacent to the second section, the third section is connected adjacent to the second section, and is located on the opposite side of the first section. ing. The fourth section is connected adjacent to the third section and is located on the opposite side of the second section. As a result, the first slope (6) is end-connected to the first section. The second inclined portion (8) is connected to the end of the fourth section, and the first inclined portion (6) and the second inclined portion (8) face each other with respect to the curved portion (7). Are arranged. Further, the first inclined portion (6) and the second inclined portion (8) are arranged on the same straight line, and the curved portion (7) is oriented toward the rotation axis (2). As a result, a gripping edge is defined within the bend (7) so that the gripping edge can be cut into the fastener head during removal of the damaged or detached fastener. Further, the first section, the second section, the third section, and the fourth section are formed as a plurality of straight sections, a plurality of curved sections, or a combination of both straight sections and curved sections. May be good.

As shown in FIG. 12, further, the plurality of engaging portions (5) of the second alternative embodiment are arranged at equal intervals in the torque tool main body (1) to form a perfect enclosing shape. ing. The lengths of the first inclined portion (6), the curved portion (7), and the second inclined portion (8) may be changed. Similarly, the angle between the first inclined portion (6), the curved portion (7), and the second inclined portion (8) may be changed to create a sharper tooth shape. To form the enclosure, the plurality of engaging portions (5) include any engaged portion (10) and an adjacent engaging portion (11). The arbitrary engaging portion (10) is any engaging portion (5) in a plurality of engaging portions (5) such that the adjacent engaging portion (11) is an engaging portion immediately beside the arbitrary engaging portion (10). It is an engaging part. More specifically, the first inclined portion (6) of any engaging portion (10) is connected to form an obtuse angle with the second inclined portion (8) of the adjacent engaging portion (11). .. In other words, since the first inclined portion (6) and the second inclined portion (8) arranged adjacent to each other are oriented at obtuse angles, the connection point between the pair of engaging portions (5) is clear. And the gripping edge is configured in the curved portion (7).

In some embodiments of the present invention, the plurality of engagement portions (5) are tapered from the top surface (32) toward the threaded opening (4) and are of the plurality of engagement portions (5). The diameter of the portion adjacent to the threaded opening (4) may be configured to be smaller than the diameter of the receiving cavity of the plurality of engaging portions (5) or the portion adjacent to the upper surface (32).

The present invention may also include an attachment function for attaching an external torque tool to the torque tool body (1) in order to increase the torque force applied to the damaged or detached fastener. As shown in FIGS. 5 and 6, in the present invention, an external tool such as an open-end wrench, a box-end wrench, a combination wrench, an adjustable wrench, or a socket wrench is attached to the torque tool body (1). An attachment body (16) and an engaging bore (17) may be further provided. Further, the attachment body (16) is arranged concentrically with the rotation axis (2) so as to coincide with the rotation axis of the torque tool. Further, the attachment body (16) is connected adjacent to the base (3) of the torque tool body (1) and is located on the opposite side of the plurality of engaging parts (5). The attachment body (16) is preferably a hexagonal design with a diameter slightly larger than the diameter of the base (3) of the torque tool body (1). However, the attachment body (16) may have a smaller diameter than the base (3), depending on the size of the base and the preferred manufacturing method or design. The engaging bore (17) penetrates the attachment body (16) along the axis of rotation (2). The engaging bore (17) is shaped to accept the male attachment member of the socket wrench, and because many socket wrenches use a square male attachment member, the engaging bore (17) The preferred shape is a square. In an alternative embodiment, the shape and design of the engaging bore (17) and the attachment body (16) may be square or cylindrical, etc., suitable for various torque tools and attachment means. In an alternative embodiment, a surface grip treatment, such as knurling, is applied to the outer surface of the attachment body (16) to increase the friction between the torque tool body (1) and any drive body. You may.

As shown in FIGS. 2 and 6, the bottom surface (31) of the attachment body (16) has an engaging bore (17) when a plurality of engaging portions (5) are driven into a fastener damaged or detached by a hammer. It is tapered away from the engaging bore (17) so that it will not hit or be damaged. In other words, the height of the attachment body (16) at the position of the engaging bore (17) is such that the bottom surface (31) can be tapered away from the engaging bore (17). ) Slightly larger than the height of the attachment body (16) for the outer surface.

As shown in FIG. 7, the release bolt (12) for removing the broken or peeled fastener includes a conical taper portion (13), a threaded shaft portion (14) and a driver portion (15). More specifically, the conical taper portion (13) and the driver portion (15) are arranged to face each other with the threaded shaft portion (14) as the center. A preferred embodiment of the threaded shaft portion (14) is a cylinder. Further, the conical tapered portion (13), the threaded shaft portion (14), and the driver portion (15) are arranged coaxially with each other, and the conical tapered portion (13) is the end portion of the threaded shaft portion (14). The driver portion (15) is concentrically connected to the threaded shaft portion (14) from the opposite end. In addition, a cavity is provided inside the driver section (15) to apply torque to the release bolt (12) when the release bolt (12) is engaged in the engagement bore (17). , The torque application handle may be configured to be able to engage in the cavity. This cavity may have any shape such as a circle or a square.

To facilitate engagement between the threaded opening (4) and the release bolt (12), the threaded shaft (14) is with the threaded thread of the threaded opening (4). Designed to match. If the damaged or detached fastener needs to be removed, the threaded shaft (14) engages with the threaded opening (4). As a result, since the driver portion (15) is offset from the torque tool body (1), the conical taper portion (13) is located adjacent to and in the plurality of engaging portions (5). To. The user can apply the appropriate clockwise or counterclockwise torque to the release bolt (12) via the driver section (15) to convert the rotational force into a linear force and remove the damaged or detached fastener from the socket. .. The internal position of the conical taper (13) within the plurality of engagements (5) allows the conical taper (13) to contact the damaged or detached fastener and disengage the fastener by the applied linear force. .. In a preferred embodiment, the driver portion (15) has a hexagonal shape. However, in an alternative embodiment, the shape of the driver portion (15) includes a square, circular, or internal drive that can be adapted to another socket wrench or other similar tool that can apply rotational force. However, it is not limited to these. The conical taper portion (13) may be formed into a cylinder, square, hexagon, or any other profile preferred by the user or manufacturer. The threaded shaft portion (14) may be a semicircle, a semicircle, or any other shape shank to which a male thread can be applied.

In the present invention, in order to remove the damaged or peeled fastener, the torque tool body (1) is arranged around the fastener, and most of the plurality of engaging portions (5) are arranged around the fastener head. To. Then, the user only needs to apply a counterclockwise torque force to the torque tool body (1) in order to rotate and remove the damaged or peeled fastener. When torque is applied to the torque tool body (1), the plurality of engaging portions (5) bite into the side surface of the fastener head, and the fastener rotates. The present invention is designed to engage a partially or completely detached fastener head. Further, in the present invention, each of the plurality of engaging portions functions as a gripping edge, so that slipping of the fastener head can be suppressed.

Although the invention of the present application has been described in the context of its preferred embodiment, many other possible modifications and variations are possible without departing from the spirit and scope of the invention claimed in the claims. Please understand that.

Claims (18)

Torque tool body and
With a threaded opening,
With multiple engaging parts,
Including release bolts
The plurality of engaging portions are arranged radially around the rotation axis of the torque tool main body.
The plurality of engaging portions are connected around the base of the torque tool body.
The threaded opening penetrates the base and
The release bolt is screw engaged with the threaded opening on the opposite side of the plurality of engaging portions.
Fastener pull-out removal tool device. The torque tool body extends outward from the cross section of the plurality of engaging portions.
The fastener extraction / removal tool device according to claim 1. Each cross section of the plurality of engaging portions includes a first inclined portion, a curved portion, and a second inclined portion.
The first inclined portion is connected to the end of the curved portion, and is connected to the end of the curved portion.
The second inclined portion is connected to the end of the curved portion, and is connected to the end of the curved portion.
The first inclined portion and the second inclined portion are arranged so as to face each other with respect to the curved portion.
The fastener extraction / removal tool device according to claim 1. The plurality of engaging portions include an engaging portion adjacent to any engaging portion, and the plurality of engaging portions include an engaging portion.
The first inclined portion of the arbitrary engaging portion is connected so as to form an obtuse angle with the second inclined portion of the adjacent engaging portion.
The fastener pull-out removal tool device according to claim 3. In addition, it includes the attachment body and the engaging bore.
The attachment body is arranged so as to be coaxial with the rotation axis.
The attachment body is connected adjacent to the base of the torque tool body on the opposite side of the plurality of engaging portions.
The engaging bore penetrates the attachment body along the axis of rotation.
The fastener extraction / removal tool device according to claim 1. The release bolt includes a conical taper, a threaded shaft and a driver.
The conical taper portion and the driver portion are arranged so as to face each other with respect to the threaded shaft portion.
The conical taper portion is connected so as to be concentric with the threaded shaft portion.
The driver portion is connected so as to be concentric with the threaded shaft portion.
The fastener extraction / removal tool device according to claim 1. The threaded shaft is engaged with the threaded opening and
The conical taper portion is arranged adjacent to the plurality of engaging portions, and the conical taper portion is arranged adjacent to the plurality of engaging portions.
The driver portion is arranged offset from the torque tool main body.
The fastener pull-out removal tool device according to claim 6. Torque tool body, threaded opening,
With multiple engaging parts,
Including release bolts
Each cross section of the plurality of engaging portions includes a first inclined portion, a curved portion, and a second inclined portion.
The plurality of engaging portions are arranged radially around the rotation axis of the torque tool main body.
The plurality of engaging portions are connected around the base of the torque tool body.
The first inclined portion is connected to the end of the curved portion, and is connected to the end of the curved portion.
The second inclined portion is connected to the end of the curved portion, and is connected to the end of the curved portion.
The first inclined portion and the second inclined portion are arranged on opposite sides to the curved portion.
The threaded opening penetrates the base and
The release bolt is screw engaged with the thread on the opposite side of the plurality of engaging portions.
Fastener pull-out removal tool device. The torque tool body extends outward from the cross section of the plurality of engaging portions.
The fastener pull-out removal tool device according to claim 8. The plurality of engaging portions include an arbitrary engaging portion and an adjacent engaging portion.
The first inclined portion of the arbitrary engaging portion is connected to the second inclined portion of the adjacent engaging portion so as to form an obtuse angle.
The fastener pull-out removal tool device according to claim 8. Including attachment body and engaging bore
The attachment body is arranged concentrically with the rotation axis.
The attachment body is connected adjacent to the base of the torque tool body on the opposite side of the plurality of engaging portions.
The engaging bore penetrates the attachment body along the axis of rotation.
The fastener pull-out removal tool device according to claim 8. The release bolt includes a conical taper portion, a threaded shaft portion, and a driver portion.
The conical taper portion and the driver portion are arranged on opposite sides to the threaded shaft portion.
The conical tapered portion is concentrically connected to the threaded shaft portion.
The driver portion is concentrically connected to the threaded shaft portion.
The fastener pull-out removal tool device according to claim 8. The threaded shaft portion is engaged with the threaded opening, and the conical taper portion is arranged adjacent to the plurality of engaging portions.
The driver portion is arranged offset from the torque tool main body.
The fastener pull-out removal tool device according to claim 12. Torque tool body and
With a threaded opening,
With multiple engaging parts,
Including release bolts
Each cross section of the plurality of engaging portions includes a first inclined portion, a curved portion, and a second inclined portion.
The release bolt includes a conical taper portion, a threaded shaft portion, and a driver portion.
The plurality of engaging portions are arranged radially around the rotation axis of the torque tool main body.
The plurality of engaging portions are connected around the torque tool body, and the plurality of engaging portions are connected to each other.
The first inclined portion is connected to the end of the curved portion, and is connected to the end of the curved portion.
The second inclined portion is connected to the end of the curved portion, and is connected to the end of the curved portion.
The first inclined portion and the second inclined portion are arranged on opposite sides to the curved portion.
The threaded opening penetrates the base and
The release bolt is screw engaged with the threaded opening on the opposite side of the plurality of engaging portions.
The threaded shaft engages the threaded opening and
The conical taper portion is arranged adjacent to the plurality of engaging portions, and the conical taper portion is arranged adjacent to the plurality of engaging portions.
The driver portion is arranged offset from the torque tool body.
Fastener pull-out removal tool device. The torque tool body extends outward from the cross section of the plurality of engaging portions.
The fastener pull-out removal tool device according to claim 14. The plurality of engaging portions include an arbitrary engaging portion and an adjacent engaging portion.
The first inclined portion of the arbitrary engaging portion is connected to the second inclined portion of the adjacent engaging portion so as to form an obtuse angle.
The fastener pull-out removal tool device according to claim 14. In addition, it includes the attachment body and the engaging bore.
The attachment body is arranged concentrically with the rotation axis.
The attachment body is connected adjacent to the base of the torque tool body on the opposite side of the plurality of engaging portions.
The engaging bore penetrates the attachment body along the axis of rotation.
The fastener pull-out removal tool device according to claim 14. The conical taper portion and the driver portion are arranged so as to face each other with respect to the threaded shaft portion.
The conical taper portion is concentrically connected to the threaded shaft portion.
The driver portion is concentrically connected to the threaded shaft portion.
The fastener pull-out removal tool device according to claim 14.

Images