JP2020508887A - Multi grip socket bit - Google Patents

Abstract

Screw bit body that enables efficient application of torque to sockets and fasteners. The screw bit body includes a plurality of laterally extending sidewalls, a first base, and a second base. The laterally extending sidewalls are radially distributed about the axis of rotation of the screw bit body and each further include a first side edge, a second side edge, a support surface, and an engagement cavity. The engagement cavities provide additional grip points and prevent slippage between the screw bit body and the socket fastener. The engagement cavity is formed vertically in the support surface and traverses the screw bit body from a first base to a second base. Specifically, the engagement cavities are disposed offset by a first distance from the first side edge and are disposed offset by a second distance from the second side edge.

Description

The present invention relates generally to various tools designed to tighten and loosen fasteners, particularly bolts and nuts, and more particularly to fastener damage or debonding during the extraction and tightening process. The invention relates to a multi-directional screwdriver bit with a non-slip function designed to prevent slippage.

Hex bolts, nuts, screws, and other similar threaded devices are used to secure and retain multiple components by engaging complementary screws called female threads. The general construction of these types of fasteners is a cylindrical shaft with external threads and a head at one end. The threads engage complementary female threads formed in the holes or nuts to secure the fastener in place while simultaneously securing the associated components. The head is a means for receiving an external torque to turn or bite the fastener against the female screw. The shape of the head is such that an external tool, such as a wrench, can apply torque to the fastener, rotate it, and to some extent engage a complementary female thread. This type of fastener is simple, very effective, inexpensive and quite common in modern architecture.

One of the most common problems in using these types of fasteners, whether male or female, is that the tool slides in or on the head. This is generally due to wear, corrosion, overtightening of the fastener or tool, or damage to the fastener head. The present invention is a driver bit design that substantially eliminates slippage. This design uses a series of segmented sections that bite into the fastener head, allowing for efficient torque transmission between the driver bit and the fastener head. The present invention eliminates the need for a general bolt removal tool that requires extra drilling work and tools. With the development of electric screwdrivers and drills, power tools have been used to apply the required torque to various fasteners and remove them. The present invention provides a double-sided driver end bit that can apply torque to the fastener in both clockwise and counterclockwise directions, and can tighten and loosen the fastener. Most driver end bits have a standardized 1/4 inch hex holder, but may be in a variety of configurations, including square ends, hexagon ends, and star ends.

It is a perspective view of the socket bit concerning this invention. FIG. 7 is a perspective view of an alternative embodiment of a socket bit according to the present invention. FIG. 7 is a top view of an alternative embodiment of a socket bit according to the present invention. FIG. 9 is a bottom view of an alternative embodiment of a socket bit according to the present invention. It is a perspective view of another embodiment of the socket bit concerning this invention. FIG. 9 is a perspective view of a further alternative embodiment of a socket bit according to the present invention. It is a perspective view of another embodiment of the socket bit concerning this invention.

All designations in the drawings are for the purpose of illustrating selected aspects of the present invention and are not intended to limit the scope of the present invention.

The present invention relates generally to torque tool accessories. More specifically, the present invention relates to a multi-grip socket bit, also known as a screw bit or screwdriver. The present invention allows a higher torque to be applied to a fastener than a similarly sized conventional driver bit without damaging the fastener head or tool. This is accomplished by using a number of engagement features that effectively grip the fastener head. The present invention is a socket bit that is compatible with a variety of torque tools, including conventional drills, bit-compatible screwdrivers, socket wrenches, and socket drivers.

FIG. 1 shows the simplest embodiment of the present invention. As shown in FIG. 1, the present invention includes at least one screw bit body (1). The screw bit body (1) is a shank that engages a socket fastener such as a socket screw or socket bolt to more quickly apply a torque force to the socket. The screw bit body (1) includes a plurality of laterally extending side walls (2), a first base (9), and a second base (10). Generally, the screw bit body (1) is a prism made of a strong metal. Each of the plurality of laterally extending sidewalls (2) engages and grips the socket fastener for efficiently transmitting torque from the torque tool to the socket fastener. The first base (9) and the second base (10) are arranged on opposite sides along a plurality of laterally extending side walls (2). Furthermore, the first base (9) and the second base (10) are oriented perpendicular to each of the laterally extending side walls (2), forming the prismatic shape of the screw bit body (1).

As shown in FIGS. 3 and 4, each laterally extending side wall (2) comprises a first side edge (3), a second side edge (4), a support surface (5), and It includes at least one engagement cavity (6). A plurality of laterally extending side walls (2) are located radially around the axis (11) of the screw bit body (1) to provide a geometry complementary to the shape of the socket fastener. The number of the plurality of laterally extending sidewalls (2) may be varied to complement various socket fixture shapes and contours. In one embodiment of the present invention, the number of the plurality of laterally extending side walls (2) is 6, and the resulting screw bit body (1) has a hexagonal cross-sectional shape. In an alternative embodiment of the present invention, the number of the plurality of laterally extending sidewalls is four, and the resulting screw bit body (1) has a square cross-sectional geometry.

The support surface (5) physically pushes against the lateral side walls of the socket fastener, in particular the head part of the socket fastener. The first side edge (3) and the second side edge (4) are arranged on opposite sides of the support surface (5). When viewed from above or below, each of the plurality of laterally extending side walls (2) has a first side edge (3) and a second side edge (4) formed by a corner of the screw bit body (1). Is configured. An engagement cavity (6) is provided vertically inside the support surface (5) and constitutes an additional grip point (teeth) on the support surface (5). This gripping point is constituted by the engaging cavity (6) and an adjacent edge (where the adjacent edge is either the first side edge (3) or the second side edge (4)). And especially the edge closest to the engagement cavity (6)). Further, the engagement cavity (6) traverses within the screw bit body (1) from the first base (9) to the second base (10). This extends the additional gripping points along the length of the screw bit body (1), maximizing the gripping engagement between the screw bit body (1) and the socket fastener. Further, the cross section (7) of the engagement cavity (6) is preferably semicircular. Due to the semi-circular shape, there is almost no high stress point in the screw bit body (1), so that the overall life of the tool can be extended. Other shapes, such as semi-rectangular, semi-square, and semi-elliptical profiles may be used for the engagement cavity (6).

In a preferred embodiment of the invention, the engagement cavities (6) are arranged for the most efficient transmission of torque. Specifically, the engagement cavity (6) is arranged offset from the first side edge (3) by a first distance (12). Similarly, the engagement cavity (6) is arranged offset by a second distance (13) from the second side edge (4). For the most efficient transmission of torque, the ratio of the first distance (12), the second distance (13) and the width (8) of the engagement cavity (6) is 1: 5: 4. Desirably.

The ratio between the first distance (12), the second distance (13) and the width (8) of the engagement cavity (6) is switched to realize the clockwise and counterclockwise designs. May be changed. As shown in FIG. 1, the present invention may be configured as a clockwise driver bit. In this embodiment, the first distance (12) is greater than the second distance (13). Specifically, the ratio of the first distance (12), the second distance (13), and the width (8) of the engagement cavity (6) is 1: 5: 4, and the torque is clockwise. May be added to the socket fastener. This design is used to screw and secure the socket fastener. In another embodiment, the present invention may be configured as a counterclockwise screw bit. In this embodiment, the first distance (12) is greater than the second distance (13). Specifically, the ratio between the first distance (12), the second distance (13), and the width (8) of the engagement cavity (6) is 5: 1: 4, in a counterclockwise direction. Torque may be applied to the socket fastener. This design is used to loosen and pull out the socket fastener.

As shown in FIG. 5, the present invention may further comprise a plurality of intermittent side walls (18). Each of the plurality of intermittent side walls (18) is a flat surface that engages a socket fastener as in a conventional screw bit design. A plurality of intermittent side walls (18) are arranged radially about the axis of rotation (11). Further, the plurality of intermittent side walls (18) are located between the plurality of laterally extending side walls (2). As a result, the plurality of intermittent side walls (18) and the plurality of laterally extending strut side walls (2) are radially alternating with one another.

The present invention also incorporates a mounting feature to allow an external torque tool to be mounted on the screw bit body (1) and to transmit torque forces to the socket fastener via the screw bit body (1). . As shown in FIG. 1, the present invention includes a mounting portion (14). The mounting portion (14) is arranged around the rotation axis (11) such that the rotation axis (11) of the mounting portion (14) and the rotation axis (11) of the screw bit body (1) coincide. . Furthermore, the mounting part (14) is connected adjacent to the second base (10). The mounting (14) preferably has a hexagonal cross section to fit within the female mounting of the external torque tool. External torque tools include, but are not limited to, electric drills, torque wrenches, pneumatic drills, socket drivers, and other similar torque tools.

FIG. 6 shows another embodiment of the present invention. The present invention further includes an engagement hole (15). The engagement hole (15) allows the present invention to be mounted on a male mounting portion of an external torque tool such as a socket wrench or a screwdriver. The engagement hole (15) is provided in the mounting portion (14) on the opposite side of the screw bit body (1) along the rotation axis (11). The engagement hole (15) is shaped to receive a male mounting portion of a socket wrench. Since most socket wrenches use a square mounting member, a square shape is desirable. In the present embodiment, it is desirable that the mounting portion (14) has a cylindrical shape. In alternative embodiments, the shape and design of the engagement holes (15) and mountings (14) may be varied to accommodate various torque tool designs and mounting means.

In the embodiment shown in FIG. 2, the present invention is embodied as a double-sided screw bit, providing both clockwise and counterclockwise screw bit bodies (1) simultaneously. In this embodiment, the screw bit body (1) includes a first screw bit body (16) and a second screw bit body (17). The attachment (14) preferably has a hexagonal cross section. The mounting part (14) is arranged so that the rotation axis (11) of the mounting part (14) and the rotation axis (11) of the first screw bit body (16) coincide. Further, the mounting portion (14) is connected adjacent to the second base (10) of the first screw bit body (16). The second screw bit body (17) shares the mounting part (14) with the first screw bit body (16). Further, the second screw bit body (17) is located on the opposite side of the first screw bit body (16), adjacent to the mounting (14), as in the conventional double-sided screw bit design. Like the first screw bit body (16), the mounting part (14) is connected to the second base (10) of the second screw bit body (17). This embodiment provides a screw bit body (1) on both sides of the mounting (14). The first screw bit body (16) is designed to screw the socket fastener clockwise.

Refer to FIG. 3 for this description. The second distance (13) of the first screw bit body (16) is greater than the first distance (12) of the first screw bit body (16). The second screw bit body (17) is designed to loosen and pull out the socket fastener (ie, a counterclockwise version). As shown in FIG. 4, the first distance (12) of the second screw bit body (17) is greater than the second distance (13) of the second screw bit body (17). This causes the additional gripping point of the second screw bit body (1) 7 to be adjacent to the second side edge (4) of the second screw bit body (17).

FIG. 5 shows an alternative embodiment of the present invention. In FIG. 5, at least one engagement cavity (6) includes a first cavity (19) and a second cavity (20). This embodiment is a simultaneous implementation of the clockwise version and the counterclockwise version of the present invention. In particular, the first cavity (19) and the second cavity (20) are arranged parallel and offset. The first cavity (19) is offset adjacent to the first side edge (3) and the second cavity (20) is offset adjacent to the second side edge (4). Be placed. This allows the user to rotate the tool according to the present invention clockwise or counterclockwise, and can utilize additional gripping without removing the tool according to the present invention from the torque tool. In this embodiment, the present invention further comprises a plurality of intermittent side walls (18), wherein the plurality of intermittent side walls (18) are preferably interspersed between the plurality of laterally extending side walls (2). .

FIG. 7 shows an alternative embodiment of the present invention. The present invention is embodied as a ball end screw bit. In this embodiment, each support surface (5) of the plurality of laterally supporting side walls (2) is concave. As a result, the screw bit body (1) has a ball-like shape as a whole. This allows the user to engage the socket fastener diagonally. This is particularly useful for fasteners that are hard to reach.

Although the invention has been described in connection with preferred embodiments thereof, it will be understood that many other modifications and variations are possible without departing from the spirit and scope of the invention as set forth in the appended claims. I want to.

Switch and change the ratio between the first distance (12), the second distance (13), and the width (8) of the engagement cavity (6) to achieve clockwise and counterclockwise designs May do it. As shown in FIG. 1, the present invention may be configured as a clockwise driver bit. In this embodiment, the first distance (12) is smaller than the second distance (13). Specifically, the ratio of the first distance (12), the second distance (13), and the width (8) of the engagement cavity (6) is 1: 5: 4, and the torque is clockwise. May be added to the socket fastener. This design is used to screw and secure the socket fastener. In another embodiment, the present invention may be configured as a counterclockwise screw bit. In this embodiment, the first distance (12) is greater than the second distance (13). Specifically, the ratio between the first distance (12), the second distance (13), and the width (8) of the engagement cavity (6) is 5: 1: 4, in a counterclockwise direction. Torque may be applied to the socket fastener. This design is used to loosen and pull out the socket fastener.

Claims (12)

A multi-grip socket bit including at least one screw bit body,
The screw bit body includes a plurality of laterally supporting side walls, a first base, and a second base,
Each of the plurality of laterally supporting sidewalls includes a first side edge, a second side edge, a support surface, and at least one engagement cavity,
The side walls supporting the plurality of lateral directions are arranged on a circumference around a rotation axis of the screw bit body,
The first side edge and the second side edge are located opposite to each other with respect to the support surface,
The engagement cavity is formed by vertically penetrating the support surface,
The engagement cavity traverses the screw bit body from the first base toward the second base;
The engagement cavity is provided at a position separated by a first distance from the first side edge,
A multi-grip socket bit, wherein the engagement cavity is provided at a second distance from the second side edge. Furthermore, it includes a mounting body and an engagement hole,
The mounting body is provided coaxially with the rotation axis,
The attachment body is provided adjacent to the second base,
The engagement hole is formed in the attachment body at a position opposite to the screw bit body, coaxially with the rotation axis,
The multi-grip socket bit according to claim 1. In addition, including the mounting body,
The mounting body is provided coaxially with the rotation axis,
The attachment body is provided adjacent to the second base.
The multi-grip socket bit according to claim 1. In addition, including the mounting body,
The at least one screw bit body includes a first screw bit body and a second screw bit body,
The attachment body is located coaxially with a rotation axis of the first screw bit body,
The attachment body is located adjacent to the second base of the first screw bit body,
The second screw bit body is coaxial with the first screw bit body,
The second screw bit main body is located on the opposite side to the first screw bit main body, adjacent to the mounting body,
The attachment body is located adjacent to the second base of the second screw bit body,
The first distance of the first screw bit body is greater than the second distance of the first screw bit body,
The second distance of the second screw bit body is greater than the first distance of the second screw bit body,
The multi-grip socket bit according to claim 1. The screw bit body further includes a plurality of intermittent side walls,
The plurality of intermittent side walls are arranged on a circumference around the rotation axis,
The plurality of intermittent sidewalls are scattered among the plurality of laterally supporting sidewalls,
The multi-grip socket bit according to claim 1. The at least one engagement cavity includes a first cavity and a second cavity;
The first cavity and the second cavity are arranged at positions parallel and offset from each other,
The first cavity is located adjacent to the first side edge;
The second cavity is located adjacent to the second side edge;
The multi-grip socket bit according to claim 1. The first distance is greater than the second distance;
The multi-grip socket bit according to claim 1. The second distance is greater than the first distance;
The multi-grip socket bit according to claim 1. The multi-grip socket bit according to claim 1, wherein a ratio of the first distance, the second distance, and the width of the engagement cavity is 1: 5: 4. The multi-grip socket bit according to claim 1, wherein the engagement cavity tapers from the first base to the second base. The multi-grip socket bit according to claim 1, wherein a cross section of the engagement cavity is semicircular. The multi-grip socket bit according to claim 1, wherein the support surface of the plurality of laterally supporting side walls is concave.

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