This application relates to tools for driving fasteners, more particularly a socket for use with a socket wrench for driving gate hinge pins.
The present invention in general relates to a socket. More particularly, it relates to a socket used in conjunction with a socket wrench for receiving asymmetric fastener heads and used for tightening, loosening, and removing driven screws and bolts.
Sockets are one of the most commonly used mechanical tools for driving fasteners, e.g. screws and bolts. The ratchet wrench with interchangeable socket is first described in U.S. Pat. No. 38,914 to J. J. Richardson, entitled Wrench. The Richardson patent first disclosed a ratcheting wrench, i.e. a socket wrench, with a cuboidal drive, i.e. square drive, for receiving removable sockets. A socket wrench is most commonly a handle with a 90° ratchet, along with a set of cylinder shaped sockets of various diameters and depths. Socket wrenches can utilize geared or gearless ratchets and are typically reversible.
Existing sockets were designed to drive fasteners having a substantially symmetrical head configured to expand around the fastener's longitudinal axis. However, not all fasteners possess symmetrical heads. One example is the common gate hinge which possesses a lag screw body having a head possessing an elongated arm running from the driven end of the fastener at a 90° angle to the fastener's longitudinal axis. A traditional socket possesses 6 or 12 equal sides to grip traditional fastener heads and would be unable to drive a gate hinge pin. Gate hinge pins are currently driven using pliers, which is very labor intensive and a time-consuming process. A socket wrench adapted to drive an asymmetric fastener head would permit the user to turn a fastener without repositioning the tool on the fastener. Thus, there is a longstanding need to design insert adapters which can be driven by a single socket driver efficiently to operate on a large range of fastener heads of different sizes and shapes.
The present invention is a socket for transmitting torque from different types of wrenches to a fastener having an offset head for driving a fastener, e.g. a gate hinge pin, and transmitting torque to the fastener shaft. Asymmetric, or irregular, fastener head may be driven by the disclosed socket. The socket preferably incorporates an elongated socket body. The socket body has a fastener head receiving end, i.e. a fastener driving end, with a plurality of internal fastener head engaging surfaces defining an axially facing internal fastener engaging opening configured to receive a fastener head. The internal fastener head engaging surfaces are configured to engage in torque transmission by engaging the corresponding drive surfaces on the fastener head when received in the fastener head receiving opening. The socket body has a socket drive end axially opposite the fastener driving end. The socket drive end has an axially facing internal drive opening, i.e. the drive socket, on the socket driving end configured to receive a driving element, typically a drive square.
The socket 10 of the present application has a center of rotation that is offset from the center of the socket along the axis extending from the distal end 12 to the proximal end 14 and aligned with the longitudinal axis of the fastener to be driven. At its distal end, the drive socket keyway 20 is configured to mate with a socket wrench drive. In one embodiment, the drive socket keyway 20 is a square shaped keyway in the socket base to receive a drive key, e.g. drive square, from a socket wrench. Different drive keys may be utilized based on the geometric configuration of the drive socket keyway 22 that receives the drive key. The keyway 22 is preferably sized to fit commercially available socket wrench drives, e.g. ¼ inch, ⅜ inch, and ½ inch. The keyway 22 preferably possesses recesses intended to mate with a spring-loaded detent ball that functions as a positive lock or stop that is commonly used to secure a socket to the drive key of a socket wrench.
In an embodiment, at least one detent ball receiving groove 27 runs from the drive face 24 of the distal end 12 through the keyway 22 to facilitate the receipt and progression of detent balls into and through the keyway 22. The keyway 22 terminates within the interior of the socket body 11. The proximal end 25 of the grooves 27 of the keyway 22 possesses a detent ball stop 29 to secure the socket 10 onto the drive key of the socket wrench so to inhibit the socket 10 from disengaging from the drive key without some action by the user.
The socket body 11 is typically, but not necessarily, a semi-hollow frustum of a geometric shape, e.g. a cylinder. The proximal end possesses a fastener receiving opening 30 or fastener keyway 30 to receive the end of fastener to which torque will be applied. Within the socket body 11 and extending distally from the fastener receiving opening 30 at the proximal end 14, a fastener receiving opening 30 is defined by a plurality of fastener engaging surfaces 34 to receive and engage the end of the fastener which will receive the applied torque. In an embodiment, the socket body outer wall 16 is slotted wherein part of the fastener end which will receive the applied torque may extend beyond the socket body outer wall 16, which will act as a fastener engaging surface 34, and which permits the fastener end to progress distally from the proximal face toward the distal face to engage the internal fastener engaging surfaces 34. Ideally, the slots are shaped and sized to receive specific fastener ends and to secure the fastener end within the socket so as to efficiently apply torque across the elements of the fastener end, e.g. the pin armature 62 of a gate pin fastener 60.
In the exemplary embodiment of a socket 10 configured to receive a gate pin 40 fastener, the pin armature 62 of the gate pin fastener 60 is received within a pin armature opening 40 in the proximal face 14 and passes distally into the pin armature slot 42 which extends through the socket body outer wall 16 to communicate with the fastener engaging surfaces 34. The pin armature stop 64 of the gate pin fastener 60 is received within the socket body 11 by passing through a pin armature stop slot opening 45 and distally into a pin armature stop slot 47 where the pin armature stop 64 communicates with the fastener engaging surfaces 34. The slots 42, 47 are sized to receive the width and length of the pin armature 62 and the pin armature stop 64 of the gate pin fastener 60, and configured to permit the gate pin fastener 60 to engage the fastener engaging surfaces 34 within the socket body 11 and the socket body outer wall 16.
The slots 42, 47 extend distally into the socket body 11 from the proximal face 14, running parallel to the axis about which the socket body 11 rotates when turned by the rotational movement of the drive key. When properly inserted, the longitudinal axis of the gate pin fastener 60 is parallel to and substantially aligned with the center of rotation of the socket 10 so that both the fastener 60 and the socket body 11 revolve around the same axis.
The socket 10 permits the application of torque from the wrench to the fastener through the application of force to the driven fastener end as communicated through the fastener engaging surfaces 34 of the socket body 11. This permits the socket 10 to reduce the amount of force required to drive a fastener into a substrate despite the existence of asymmetrical elements on the driven end of a fastener that prevent it from being received into a typical socket 10. In the example of a gate pin fastener 60 the user is required to use pliers to turn the gate pin fastener 60 by applying torque to the pin armature 62 and/or pin armature stop 64, risking the alignment and/or surface integrity of the pin armature 62. However, this conveys the rotational stress to the fastener shaft/pin armature stop joint 66 of the gate fastener pin 60 or any similar fastener having an asymmetrical fastener end 68. The application of torque to of all of the physical elements of the asymmetrical fastener end 68 helps to distribute torque across the fastener end rather than a fastener shaft/fastener end joint 66 between the fastener shaft 69 and the fastener end 68. The secure gripping of an asymmetrical fastener end 68 is important to prevent damage or excessive wear to a fastener and to provide improved control of a fastener when it is being driven.
Further embodiments of the socket are intended to encompass other asymmetrical fastener heads. The key principle being the use of a socket having an offset key way that aligns with the longitudinal axis of the fastener and the remaining body of the socket having a geometry configured to receive and secure an asymmetrical head, preferably to permit the distribution of torque outside of a single plane of rotation and to take advantage of unique fastener end geometries that would typically not be amenable to use with a socket wrench.
The socket is preferably manufactured of a material that is harder than the fastener and most preferably from steel or a steel alloy. The socket is preferably deep enough to allow the entire fastener end to be inserted within the socket body 11 to permit the application of torque across the entire fastener end so that the fastener shaft/fastener end joint lies within the socket body 11. Preferably, the socket is deep enough to seat the fastener head adjacent to the drive socket 20 to enhance stability.
The provided example of a gate hinge pin as the driven fastener is intended only for exemplary purposes only and is not intended to limit the scope of the device to gate hinge pins. Alternative embodiments are understood to become obvious to one skilled and the art upon reading this disclosure.
This application claims the benefit of U.S. Provisional Patent Application 62/597,547 filed on Dec. 12, 2018.
Number | Date | Country | |
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62597547 | Dec 2017 | US |