Archery, whether grounded in target shooting or hunting, has maintained popularity over the years. Along with this popularity, many features have been developed to improve the use, accuracy and power of an archery bow. One such add-on is the wrist sling (also referred to as an archery sling or simply, a sling) which is positioned over or around the wrist of a user. Typically, the sling is secured to the bow, commonly at a location near the hand grip of the bow to easily accommodate the user's wrist. During use, a wrist sling keeps the bow connected to the user when the user releases the grip of the bow whether intentionally or by accident. For example, the archery community has concluded that merely bracing the grip with your hand, rather than actually gripping the grip, is an integral part of accurate arrow shooting. Of course, by not gripping the bow, the bow will fall out of the user's hand upon release of the tension on the bow string, and thus release of the arrow. As such, the sling keeps the bow connected to the user's arm for simplified and more efficient reloading as well as preventing the bow from falling to the ground—a particular issue when for example the user is positioned up in a tree while hunting.
Further, current slings known in the prior art are affixed to bows using brackets having locking screws, or the like, such that a hunter must carry with him an appropriate tool or instrument to adjust (tighten or loosen) the locking screws to adjust the sling as desired. This is often a problem when the locking screws loosen during use and the hunter must tighten the locking screws during the hunt. This can be particularly troublesome if the hunter forgets to bring the tool along for the hunt.
Another issue faced in archery is vibration or harmonic forces due primarily to the use of the bow (e.g., release of an arrow). Current prior art add-ons include harmonic or vibration dampeners that are attached to the bow and which are intended to reduce such forces. However, such dampeners are cumbersome, add weight to the bow, and increase the difficulty in maneuvering the bow due to the dampener extending from the bow. This, again, is a particular problem when hunting and, for example, positioned within the branches of the tree, such that the dampener could get snagged on a branch while maneuvering the bow.
As such, current add-ons such as wrist slings and associated brackets and vibration dampeners can be difficult to adjust, can be cumbersome, and may interfere with the use of the bow. Thus, there is a need in the art for improved features, such as wrist slings and brackets, that overcome many of these deficiencies.
The present invention, generally relates to a bracket for use with an archery bow for securing a sling to the bow. The bracket can include a vibration dampener for dampening forces exerted on a user during use of the bow and/or a hand-adjustable securing element for securing the sling to the bracket. The bracket of the present invention provides many benefits including but not limited to: providing a compact device which provides multiple functions, providing numerous features and functions which are easy to use, providing a compact device which takes up a minimal amount of space on the bow and also minimizes weight added to the bow, and providing numerous features and functions in a compact device where such features are concealed or disguised to maintain an aesthetically pleasing device.
In one embodiment, the present invention includes a bracket for use with an archery bow, including a main body having a length extending between a first end and a second end, at least one throughbore through which a portion of a sling can be positioned, at least one passageway intersecting the throughbore, and at least one securing element positionable through the passageway and into at least a portion of the throughbore, the securing element adapted to releasably secure the portion of the sling within the throughbore.
Continuing with this embodiment, the securing element can include a threaded portion and the passageway includes a matching thread which can accept the thread of the securing element such that the securing element is hand-adjustable. Further, the throughbore can be positioned transverse to the length of the main body (and optionally, can extend perpendicular to the longitudinal axis) and the passageway may extend from one of the first or second ends of the main body, along a longitudinal axis of the main body, and to the throughbore.
Further, the main body may also include a second throughbore through which a second portion of the sling can be positioned, a second passageway intersecting the throughbore, and a second securing element positionable through the second passageway and into at least a portion of the second throughbore, the second securing element adapted to releasably secure the second portion of the sling within the second throughbore. Additionally, both the first and second securing elements can include a threaded portion and the first and second passageways each includes a matching thread which accepts the thread of the respective first and second securing elements such that the first and second securing elements are hand-adjustable, each of the first and second securing elements includes a handle portion extending from the threaded portion, the first passageway extends from the first end of the main body, along a longitudinal axis of the main body, and to the first throughbore, the first throughbore extends perpendicular to the longitudinal axis, and the handle portion of the first securing element is positioned adjacent the first end of the main body from which the first passageway extends, and the second passageway extends from the second end of the main body, along the longitudinal axis of the main body, and to the second throughbore, the second throughbore extends perpendicular to the longitudinal axis, and the handle portion of the second securing element is positioned adjacent the second end of the main body from which the second passageway extends.
In another embodiment, the present invention is a bracket for use with an archery bow, including a main body having a length extending between a first end and a second end, a first throughbore and a second throughbore through which a first portion and a second portion of a sling, respectively, can be positioned, and at least one vibration dampener. The bracket can also include two or more vibration dampeners, such that the first vibration dampener can be positioned at the first end of the main body and the second vibration dampener can be positioned at the second end of the main body. The main body can also include a longitudinal axis extending along the length and the first and second vibration dampeners can be positioned to dampen forces occurring perpendicular to the longitudinal axis. Further, the first and second vibration dampeners may be positioned substantially within the volume of the main body and at the respective first and second ends.
In yet another embodiment, the present invention includes a bracket for use with an archery bow, including a main body having a length extending between a first end and a second end, at least one throughbore through which a portion of a sling can be positioned, at least one passageway intersecting the throughbore, at least one securing element positionable through the passageway and into at least a portion of the throughbore, the securing element adapted to releasably secure the portion of the sling within the throughbore, and at least one vibration dampener.
Continuing with this embodiment, the securing element can include a threaded portion and the passageway includes a matching thread which can accept the thread of the securing element such that the securing element is hand-adjustable. Further, the throughbore can be positioned transverse to the length of the main body (and optionally, can extend perpendicular to the longitudinal axis) and the passageway may extend from one of the first or second ends of the main body, along a longitudinal axis of the main body, and to the throughbore.
Further, the main body may also include a second throughbore through which a second portion of the sling can be positioned, a second passageway intersecting the throughbore, a second securing element positionable through the second passageway and into at least a portion of the second throughbore, the second securing element adapted to releasably secure the second portion of the sling within the second throughbore, and a second vibration dampener. Additionally, both the first and second securing elements can include a threaded portion and the first and second passageways each includes a matching thread which accepts the thread of the respective first and second securing elements such that the first and second securing elements are hand-adjustable, each of the first and second securing elements includes a handle portion extending from the threaded portion, the first passageway extends from the first end of the main body, along a longitudinal axis of the main body, and to the first throughbore, the first throughbore extends perpendicular to the longitudinal axis, and the handle portion of the first securing element is positioned adjacent the first end of the main body from which the first passageway extends, and the second passageway extends from the second end of the main body, along the longitudinal axis of the main body, and to the second throughbore, the second throughbore extends perpendicular to the longitudinal axis, and the handle portion of the second securing element is positioned adjacent the second end of the main body from which the second passageway extends.
The vibration dampener can be positioned anywhere on the bracket, such as at one of the first or second ends of the bracket. If two vibration dampeners are included, the first vibration dampener can be positioned at the first end of the main body and the second vibration dampener can be positioned at the second end of the main body. In a preferred embodiment, the securing elements include a handle portion, and the first vibration dampener can be positioned within the handle portion of the first securing element and the second vibration dampener can be positioned within the handle portion of the second securing element. The main body can also include a longitudinal axis extending along the length and the first and second vibration dampeners can be positioned to dampen forces occurring perpendicular to the longitudinal axis. For example, the passageway can extend from one of the first or second ends of the main body, along a longitudinal axis of the main body, and to the throughbore, the throughbore can extend perpendicular to the longitudinal axis, and the handle portion may be positioned adjacent the first or second end of the main body from which the passageway extends, such that the vibration dampener (or dampeners) may be positioned substantially within the volume of the handle portion (or portions) of the securing elements such that it is positioned perpendicular to the longitudinal axis.
In a further embodiment, the present invention includes a method of dampening forces exerted on a user of an archery bow, the forces resulting from the release of an arrow from the bow, including the step of connecting a bracket to the bow, the bracket comprising a main body having a length extending between a first end and a second end, a first throughbore and a second throughbore through which a first portion and a second portion of a sling, respectively, can be positioned, and at least one vibration dampener, wherein the main body includes a longitudinal axis extending along the length and the at least one vibration dampener is positioned to dampen forces occurring perpendicular to the longitudinal axis.
In another embodiment, the present invention includes a method of hand-adjusting a sling on an archery bow, including the steps of connecting a bracket to the bow, the bracket comprising a main body having a length extending between a first end and a second end, a first throughbore through which a first portion of the sling can be positioned, a second throughbore through which a second portion of the sling can be positioned, a first securing element in communication with at least a portion of the first throughbore, and a second securing element in communication with at least a portion of the second throughbore; positioning the sling through the first and second throughbores; hand-adjusting the first and second securing elements to releasably secure the first and second portions of the sling within the respective first and second throughbores; using the bow to fire an arrow to determine whether the sling is in a desired position; hand-adjusting the first and second securing elements to release the first and second portions of the sling; re-positioning the sling through the first and second throughbores such that third and fourth portions of the sling are positioned within the respective first and second throughbroes; and hand-adjusting the first and second securing elements to releasably secure the third and fourth portions of the sling within the respective first and second throughbores. The method can further include the steps of using the bow a second time to fire a second arrow to determine whether the sling is in a desired position; hand-adjusting the first and second securing elements to release the third and fourth portions of the sling; re-positioning the sling through the first and second throughbores such that fifth and sixth portions of the sling are positioned within the respective first and second throughbroes; and hand-adjusting the first and second securing elements to releasably secure the fifth and sixth portions of the sling within the respective first and second throughbores. Further, the first and second securing elements can include first and second handle portions and the steps of hand-adjusting includes rotating the first and second handle portions to rotate the threaded portions of the first and second securing elements relative to the threads of the first and second passageways.
In still another embodiment, the present invention includes a method of hand-adjusting a sling on an archery bow, including the steps of connecting a bracket to the bow, the bracket comprising a main body having a length extending between a first end and a second end, a first throughbore through which a first portion of the sling can be positioned, a second throughbore through which a second portion of the sling can be positioned, a first securing element in communication with at least a portion of the first throughbore, and a second securing element in communication with at least a portion of the second throughbore; positioning the sling through the first and second throughbores; hand-adjusting the first and second securing elements to releasably secure the first and second portions of the sling within the respective first and second throughbores; using the bow to fire an arrow to determine whether the sling is in a desired position; hand-adjusting one of the first and second securing elements to release one of the first and second portions of the sling; re-positioning the sling through one of the first and second throughbores such that a third portion of the sling is positioned within the one of the first and second throughbroes; and hand-adjusting the one of the first and second securing elements to releasably secure the third portion of the sling within the one of the first and second throughbores.
In a further embodiment, the present invention includes a kit having at least one bracket and a plurality of slings. The kit may further include a plurality of brackets wherein each bracket can accommodate a particular sling or, alternatively, each bracket can accommodate any of the plurality of slings. The kit can further include a bow.
The archery bow 90 may be any style desired, and further the bracket 10 may be secured to the bow at any location desired and in any way as desired. As illustrated, the bracket may be secured to the bow adjacent to or on the grip 91 using a connection element 70 such as for example a screw, threaded bolt (with an associated nut or without, as illustrated), snap fit connection, tie fastener, or the like.
The wrist sling 80 may be any as known in the art which connects the user to the bow upon the user's release of the bow, as discussed above. In one alternative example, and in a preferred embodiment, the sling 80 can be a Stiffy Sling™ (LOC OutdoorZ, Ligonier, Ind.) which is a sling using a braided material that is sufficiently rigid such that it can be shaped and positioned, and remain in such a shape and position, on the bow. For example, prior art slings are flaccid and thus, hang downward or sag on the bow, which can make positioning the user's hand and arm through the sling and to the grip on the bow cumbersome. As illustrated in
The bracket 10, continuing with this embodiment as illustrated in
Along the length of the bracket 10 is positioned at least one throughbore 14, though it is preferred that the main body 11 include first and second throughbores 14, 15, positioned on either side of connection element 70 and towards the first and second ends 12, 13, respectively. As illustrated, the throughbores may be positioned through the bracket transverse to a longitudinal axis positioned along the length of the bracket 10. Extending from each of the first and second throughbores 14, 15 to the first and second ends 12, 13, respectively, are first and second passageways (not shown here, but illustrated as passageway 216 in second end 213 in
As illustrated, the first throughbore 14 is shaped and sized to allow a first portion 81 of sling 80 to be positioned therethrough and the second throughbore 15 is shaped and sized to allow a second portion 82 of sling 80 to be positioned therethrough. The sling may freely move through the throughbores such that a user can position the sling relative to the bracket as desired.
The bracket of this embodiment also includes a first securing element 20a and a second securing element 20b positioned through the first and second passageways (as illustrated in
In another embodiment, as illustrated in
The bracket 110 of this embodiment includes a main body 111 having a length extending between a first end 112 and a second end 113 and is shaped similarly as the embodiment of
Continuing with this embodiment, bracket 110 includes at least one vibration dampener 140. As illustrated, bracket 110 can include two vibration dampeners 140a, 140b, the first dampener 140a positioned at the first end 112 of the main body and the second vibration dampener 140b positioned at the second end 113 of the main body. While
The vibration dampeners 140a, 140b may be any type desired which are capable of suppressing vibrational forces associated with the use of the bow. For example, and as illustrated, the dampeners may be Harmonic Dampers® (Mathews, Inc., Sparta, Wis.). By integrating the dampeners 140a, 140b within the main body 111, bracket 110 provides at least two functions (connection of the sling to the bow and vibrational dampening) within its compact, lightweight size. Further, by positioning the dampeners in a position perpendicular to the axis of the bracket, they can more efficiently and effectively suppress forces associated with use of the bow. It is envisioned that multiple vibration dampeners can be made available to the user such that the user may exchange one dampener for another. Such multiple dampeners may all be the same, or may differ in color, dampening ability, size, or the like, to provide differing functional and/or aesthetic qualities. Of course, if multiple dampeners are available to the user, they may all be the same and may be exchanged in the event of breakage or loss of a dampener, for example.
In yet another embodiment, illustrated in
The bracket 210 of this embodiment includes a main body 211 having a length extending between a first end 212 and a second end 213 and is shaped similarly as the embodiments of
As above, the first throughbore 214 is shaped and sized to allow a first portion 81 of sling 80 to be positioned therethrough and the second throughbore 215 is shaped and sized to allow a second portion 82 of sling 80 to be positioned therethrough. The sling may freely move through the throughbores such that a user can position the sling relative to the bracket as desired.
Similar to the embodiment of
Continuing with this embodiment, bracket 210 includes at least one vibration dampener 240, similar to dampeners 140a, 140b of bracket 110 in
For example,
The various brackets of the present invention may be included in various systems and kits. In one embodiment, the present invention includes a system including a bracket 10, 110, 210 and a sling 80. Additionally, the system may also include a bow 90. The bracket and optionally, the sling, may be positioned on the bow at manufacture or may be positionable on the bow by the intended user.
In another embodiment, the present invention includes a kit having at least one bracket 10, 110, 210 and a plurality of slings 80. The kit may further include a plurality of brackets wherein each bracket can accommodate a particular sling or, alternatively, each bracket can accommodate any of the plurality of slings. Such a kit can allow a user to select a particular dampener and/or a particular bracket, which provides a desired dampening force, color combination, or the like, based on the available dampeners (as discussed above). The kit may further include a bow which may accommodate any one of the brackets and any one of the slings at a time.
The present invention also includes various methods of using the bracket of the present invention. While below are provided a few exemplary methods of using the bracket, other such methods are also envisioned.
In one embodiment, the present invention includes a method of dampening forces exerted on a user of an archery bow, the forces resulting from the release of an arrow from the bow, including the step of connecting a bracket (for example, either bracket 110 or 210) to the bow 90 using a connection element (170 or 270), the bracket comprising a main body (111, 211) having a length extending between a first end and a second end (112, 113 or 212, 213), a first throughbore and a second throughbore (114, 115 or 214, 215) through which a first portion 81 and a second portion 82 of a sling 80, respectively, can be positioned, and at least one vibration dampener (140 or 240), wherein the main body includes a longitudinal axis extending along the length and the at least one vibration dampener is positioned to dampen forces occurring in any direction relative to the longitudinal axis, and particularly those forces perpendicular to the longitudinal axis.
The bracket may be secured to the bow in any position desired, though a position along the front surface of the bow, adjacent to or at the grip, is preferred. The bracket may further include first and second vibration dampeners (140a, 140b or 240a, 240b). The forces dampened by this method, for example, those occurring perpendicular to the longitudinal axis of the bracket, may be those associated with the release of the arrow form the bow, as directed by the user. Of course, the dampeners of this method can dampen other forces occurring in any direction relative to the longitudinal axis.
In another embodiment, the present invention includes a method of hand-adjusting a sling 80 on an archery bow 90, including the steps of connecting a bracket (for example, either bracket 10 or bracket 210) to the bow using a connection element (70 or 270), the bracket comprising a main body (11 or 211) having a length extending between a first end (12 or 212) and a second end (13 or 213), a first throughbore (14 or 214) through which a first portion 81 of the sling can be positioned, a second throughbore (15 or 215) through which a second portion 82 of the sling can be positioned, a first securing element (20a or 220a) in communication with at least a portion of the first throughbore and a second securing element (20b or 220b) in communication with at least a portion of the second throughbore; positioning the sling through the first and second throughbores; hand-adjusting the first and second securing elements to releasably secure the first and second portions of the sling within the respective first and second throughbores; using the bow to fire an arrow to determine whether the sling is in a desired position; hand-adjusting the first and second securing elements to release the first and second portions of the sling; re-positioning the sling through the first and second throughbores such that third and fourth portions of the sling are positioned within the respective first and second throughbroes; and hand-adjusting the first and second securing elements to releasably secure the third and fourth portions of the sling within the respective first and second throughbores. The third and fourth portions may be adjacent to the first and second portions in that, by re-positioning the sling to have the third and fourth portions positioned within the respective first and second throughbores, the sling is moved in either a forward or backward direction (e.g., forwards or backwards to shrink or lengthen, respectively, the size of the sling).
Furthermore, the bracket may include a first passageway (such as passageway 216 in
Continuing with this embodiment, the method can further include the steps of using the bow a second time to fire a second arrow to determine whether the sling is in a desired position; hand-adjusting the first and second securing elements to release the third and fourth portions of the sling; re-positioning the sling through the first and second throughbores such that fifth and sixth portions of the sling are positioned within the respective first and second throughbroes; and hand-adjusting the first and second securing elements to releasably secure the fifth and sixth portions of the sling within the respective first and second throughbores. The fifth and sixth portions may be adjacent to the third and fourth portions (and/or the first and second portions) in that, by re-positioning the sling to have the fifth and sixth portions positioned within the respective first and second throughbores, the sling is moved in either a forward or backward direction (e.g., forwards or backwards to shrink or lengthen, respectively, the size of the sling). This step may be repeated as necessary to attain the proper positioning of the sling relative to the bracket, and thus, the bow.
Additionally, the first and second securing elements can include first and second handle portions and the steps of hand-adjusting includes rotating the first and second handle portions to rotate the threaded portions of the first and second securing elements relative to the threads of the first and second passageways.
In still another embodiment, the present invention includes a method of hand-adjusting a sling 80 on an archery bow 90, including the steps of connecting a bracket (for example, either bracket 10 or bracket 210) to the bow using a connection element (70 or 270), the bracket comprising a main body (11 or 211) having a length extending between a first end (12 or 212) and a second end (13 or 213), a first throughbore (14 or 214) through which a first portion 81 of the sling can be positioned, a second throughbore (15 or 215) through which a second portion 82 of the sling can be positioned, a first securing element (20a or 220a) in communication with a portion of the first throughbore and a second securing element (20b or 220b) in communication with a portion of the second throughbore; positioning the sling through the first and second throughbores; hand-adjusting the first and second securing elements to releasably secure the first and second portions of the sling within the respective first and second throughbores; using the bow to fire an arrow to determine whether the sling is in a desired position; hand-adjusting one of the first and second securing elements to release one of the first and second portions of the sling; re-positioning the sling through one of the first and second throughbores such that a third portion of the sling is positioned within the one of the first and second throughbroes; and hand-adjusting the one of the first and second securing elements to releasably secure the third portion of the sling within the one of the first and second throughbores. The third portion may be adjacent to either of the first and second portions in that, by re-positioning the sling to have the third portion positioned within the particular first or second throughbore, the sling is moved in either a forward or backward direction (e.g., forwards or backwards to shrink or lengthen, respectively, the size of the sling).
Furthermore, the bracket may include a first passageway (such as passageway 216) intersecting the first throughbore, a second passageway (such as passageway 216) intersecting the second throughbore, the first securing element (20a or 220a) positionable through the first passageway and into at least a portion of the first throughbore, and the second securing element (20b or 220b) positionable through the second passageway and into at least a portion of the second throughbore, wherein the first and second securing elements each include a threaded portion 221 and the first and second passageways include a matching thread 217 which accepts the threaded portion of the first and second securing elements such that the securing elements are hand-adjustable.
As with the previously disclosed method, one of the first or second securing elements may be hand-adjusted such that the sling may be re-positioned again such that now a fourth portion is positioned within the particular first or second throughbore. This step may be repeated as necessary to attain the proper positioning of the sling relative to the bracket, and thus, the bow.
Although the invention herein has been described with reference to particular embodiments, it is to be understood that these embodiments are merely illustrative of the principles and applications of the present invention. It is therefore to be understood that numerous modifications may be made to the illustrative embodiments and that other arrangements may be devised without departing from the spirit and scope of the present invention as defined by the appended claims.
The present application claims the benefit of the filing date of U.S. Provisional Patent Application Nos. 61/731,245 filed Nov. 29, 2012 and 61/639,722 filed Apr. 27, 2012, the disclosures of which are hereby incorporated herein by reference as if fully set forth herein.
Number | Name | Date | Kind |
---|---|---|---|
3055354 | Gates | Sep 1962 | A |
3204626 | Morneau | Sep 1965 | A |
3572312 | Foster | Mar 1971 | A |
3812834 | Saunders | May 1974 | A |
4714071 | Saunders | Dec 1987 | A |
4777666 | Beverlin | Oct 1988 | A |
4836177 | Williams | Jun 1989 | A |
5065732 | Smith | Nov 1991 | A |
5531211 | Wilfong, Jr. | Jul 1996 | A |
5894672 | Ellenburg et al. | Apr 1999 | A |
6173707 | Howell et al. | Jan 2001 | B1 |
7954175 | Platt | Jun 2011 | B2 |
7954481 | Barnard | Jun 2011 | B2 |
8025047 | Saunders | Sep 2011 | B2 |
8347870 | Mahutga | Jan 2013 | B1 |
8360044 | Platt | Jan 2013 | B2 |
8646440 | Albanese et al. | Feb 2014 | B1 |
8662064 | Campbell | Mar 2014 | B1 |
8695580 | LoRocco | Apr 2014 | B2 |
8776772 | Albanese | Jul 2014 | B1 |
8955504 | Albanese et al. | Feb 2015 | B1 |
20090095270 | Graves | Apr 2009 | A1 |
20100031946 | Lorocco | Feb 2010 | A1 |
Number | Date | Country | |
---|---|---|---|
20130284159 A1 | Oct 2013 | US |
Number | Date | Country | |
---|---|---|---|
61639722 | Apr 2012 | US | |
61731245 | Nov 2012 | US |