The present invention relates generally to slingshots and their components and, more particularly, to a collapsible locking slingshot with a unique quick-release interchangeable band replacement and safety system. The present invention also relates to a self-centering, open-pocket slingshot pouch and an improved dual-tapered band.
Slingshots commonly are used as toys, for recreation, and for hunting. Although slingshots have existed for centuries, the basic design and mechanics have remained constant over time. Quite simply, a traditional slingshot comprises a handle and a pair of arms extending divergently upward from the handle. An elastic band is attached between the arms. Typically, centered on the elastic band is a pouch designed to hold a projectile. After a projectile is placed in the pouch, the pouch is pulled backwards, away from the arms, thereby extending and stretching the elastic band to create potential energy. When the pouch is released, the potential energy of the elastic band is transformed to kinetic energy which is transferred to the projectile through the pouch. The projectile then is thrust forward, out of the pouch, and away from slingshot shooter and toward a desired target.
Various design enhancements have been made over the years in an attempt to improve the functionality and safety of slingshots. For example, such improved slingshot devices include wrist-braces to help stabilize shots, foldable designs to make devices more portable, aiming mechanisms to improve accuracy, multi-band designs to improve band life and increase shot speed, and pulley assemblies to produce maximum projectile velocity with minimum force exertion by the user. Despite the various improvements made to slingshots over the years, there still exists a need for a slingshot which is collapsible and lockable, which has a quick-release band replacement system, and which may include a self-centering, open-pocket pouch and dual-tapered band. The present invention satisfies that need.
The unique design of the components of the slingshot of the present invention creates several performance and safety features never before seen in a slingshot device. First, the slingshot of the present invention collapses or folds into a lockable case. This feature not only improves the slingshot's safety, but it also enhances protection and longevity of the slingshot's components by creating a protected inner case that shields the delicate elastic band from abrasion and ultraviolet radiation. Second, the slingshot of the present invention uses a unique shoot-over design in which the arms are substantially parallel (rather than generally perpendicular) to the shooter's arm during operation. This shoot-over design allows the band to dissipate any post-firing residual energy in a more safe and controlled manner than in prior slingshot designs. Third, the slingshot of the present invention utilizes a quick-release band replacement and safety mechanism which is engineered to accept both flat and tubular bands, permit rapid band replacement, and allow for safe disengagement of the mechanism in the event of band or component failure. Additionally, the slingshot of the present invention can incorporate a unique self-centering, open-pocket pouch design that increases shot speed and accuracy by minimizing side contact between the pouch and the ammunition. Finally, the slingshot of the present invention can include a uniquely-engineered dual-tapered band design which decreases band wear while maintaining virtually all of the speed and pull smoothness associated with traditional tapered band designs.
It is therefore a principal object of the present invention to provide a slingshot with improved safety and performance features. An additional principal object of the present invention is to provide a collapsible, folding slingshot which is compact and which protects the delicate band from abrasion and ultraviolet radiation. Another object of the invention is to provide a collapsible, folding slingshot which may be locked in a folded position to prevent the slingshot from being used. A further object of the present invention is to provide a slingshot which, when unfolded, transforms into a gauntlet-shaped brace designed to protect the shooter's hand, wrist, and arm. Yet another object of the present invention is to provide a slingshot with a gauntlet-shaped brace designed to stabilize and align the pulling forces to create a straighter shot and reduce gripping pressure. It is another object of the present invention to provide a slingshot which has ideal handle/brace ergonomics, without the need for high hand strength or retainer straps, which keeps the slingshot from twisting out of the shooter's hand. Another object of the present invention is to provide a slingshot with a shoot-over design which minimizes the recoil and shock to the shooter's hand and arm, and which permits residual energy in the band to be safely dispersed away from the shooter and the slingshot's components. A further object of the present invention is to provide a slingshot with a large, internally embedded, metal-core axis, which permits the slingshot to be detected by metal detectors.
An important object of the present invention is to provide a quick release band replacement and safety system which minimizes the time required to change a slingshot band, while maximizing safety by utilizing a groove-and-clip design engineered to eject the clip forward, away from the shooter, should a slingshot component fail during pull-back. Yet another object of the present invention is to provide a slingshot with a quick release band replacement and safety system which can utilize by flat bands and tubular bands. A further object of the present invention is to provide a slingshot design with a quick release band replacement and safety system that includes means to adjust the band length, from long to short or any length in between, to achieve the fastest speed, the easiest pull, and/or the greatest band life.
An additional object of the present invention is to provide a slingshot which is designed with engineered failsafe break points to maximize protection of the shooter in case of component failure. Another object of the present invention is to provide a slingshot which is easy to assemble, use, fold, unfold, and lock.
Yet another object of the present invention is to provide a dual-tapered band which is designed to maintain the ease-of-pull and high velocity of conventional tapered bands, while at the same time decreasing the wear of the band by focusing the band's flexing away from the pouch.
An additional object of the present invention is to provide a self-centering, open-pocket pouch which includes integrated exit ports to permit the ammunition to exit the pouch without touching the sides of the pouch, thereby increasing the speed and accuracy of shooting a single or multiple ammunition load. It is another object of the present invention to provide a self-centering, open-pocket pouch which is molded flat to help the pouch open with air pressure to ensure the ammunition exits the pouch cleanly.
Numerous other advantages and features of the invention will become readily apparent from the following detailed description of the invention and the embodiments thereof, from the claims, and from the accompanying drawings.
A fuller understanding of the foregoing may be had by reference to the accompanying drawings, wherein:
a is a perspective view of the collapsible locking slingshot of the present invention showing the fully-assembled slingshot, band, and pouch;
b-3e are perspective views showing the steps to engage the locking clip into the arm to secure the band;
While the invention is susceptible to embodiments in many different forms, there are shown in the drawings and will be described herein, in detail, the preferred embodiments of the present invention. It should be understood, however, that the present disclosure is to be considered an exemplification of the principles of the invention and is not intended to limit the spirit or scope of the invention and/or claims of the embodiments illustrated.
A collapsible locking slingshot of the present invention is comprised of a ten primary components: a front panel, a rear panel, a handle, an axle, a pair of arms, a pair of locking clips, a dual-tapered band, and a self-centering open-pocket pouch. It will be appreciated, however, the collapsible locking slingshot device itself (comprising only the front panel, rear panel, handle, axle, arms, and locking clips) is independent from the dual-tapered band and the self-centering, open-pocket pouch. Although the band and pouch designs disclosed herein are intended to complement the particular collapsible locking slingshot device disclosed herein, the band and pouch of the present invention also may be used with other prior art slingshot devices. Similarly, the particular collapsible locking slingshot device of the present invention may be used with prior art bands (single, multiple, flat, tubular, etc.) and pouches.
Collapsible Locking Slingshot
As shown in
The ends 38 of the axle 18 slide into bores 40a and 40b defined on the arms 20a and 20b. The center portion 42 of the axle 18 slides through an aperture 44 on the front panel 12 and a bore 46 on the handle 16, thereby connecting the arms 20a and 20b and handle 16 to the front panel 12. It is contemplated that the arms 20a and 20b and the handle 16 are each rotatably connected to the axle allowing for independent rotation thereof. Alternatively, the arms may be secured to the axle and will rotate with the rotation of the axle therefore the arms will always be in alignment with each other.
Positioned at the other end of the arms 20a and 20b are grooves 50a and 50b, which are designed to matingly engage the locking clips 22a and 22b. The locking clips 22a and 22b (illustrated in
The fully assembled collapsible locking slingshot appears in
Further, this groove-and-clip design is engineered to eject the clips 22a and 22b forward, away from the slingshot user, if a portion of the arms 20a or 20b, or the grooves 50a or 50b, breaks during pull-back. This minimizes the likelihood of injury due to parts being connected to the band. Once inserted and when the band 60 is pulled back the ends 62 and 63 of the band 60 would exert an outward and forward force on the clips 22a and 22b. If a break occurs, while the end of the band 60 may thrust backwardly towards the slingshot user, the clip would be forced outwardly and forwardly away from the slingshot user.
A further advantage of the groove-and-clip design of the present invention is that the band 60 can be adjusted and readjusted in length, simply by repositioning the band 60 within the clips 22a and 22b and the grooves 50a and 50b. By adjusting the length of the ends 62 and 63 of the band 60 that extends out of the bottom 66 of the grooves 50a and 50b, but not changing the draw distance between the band anchoring point on the slingshot and the pouch's anchoring point for any particular individual, the most efficient use of the band can be achieved. In the prior art, when band lengths stay the same and anchor points on the slingshot are changed, then generally what changes is the amount of pull. However, by making it quick and easy to change a band from long to short and back to long any number of times, the band can be tuned to shoot at the fastest speed, or for the easiest pull, or at an ideal setting where fastest speed and longest band life are balanced.
In its fully open configuration, shown in
Finally, the unique shoot over design of the present invention allows the band to dissipate residual energy left over after firing, minimizing recoil or shock to the user's hand and arm. Staged energy dissipation is achieved when the band travels forward without running into other components. For example, the band in the present invention does not run into prior art rearward facing prongs used to hold tubular bands, the post of prior art shoot-over designs, or the band retainer guides on prior art pulley-equipped units. The collapsible locking slingshot 10 employs a pair of arms 20a and 20b that when in the firing position are substantially parallel to the slingshot user's arm, unlike prior art devices that have the arms perpendicular or at an angle to the user's arm. In the present invention, most, if not all, of the band travels past arms without contacting them. As the band progresses forward its energy is diverted into a downward circular arch, allowing residual energy to dissipate over a much longer stroke than prior art systems. If, by chance, any portion of the band ends up folding into the arms, the arms are designed to gently deflect this peripheral contact.
As discussed above, the collapsible locking slingshot of the present invention incorporates a padlock locking bay into the design by allowing the part 34 of the lower portion 36 of the handle 16 to protrude through the port 32 in the rear panel 14. This allows the slingshot to be locked securely using virtually any size of padlock that fits in the exposed portion of the handle 16. Even if a padlock is not used, the rear panel 14 still snaps closed, as described above, to prevent accidental unfolding of the device 10. The closed case also forms a protective housing for the delicate band 60 and pouch 72, shielding them from abrasion and ultraviolet radiation. This extra level of protection extends the life of the band 60 and the pouch 72, since slingshots generally are used far less than they are unused.
An important safety feature of the collapsible locking slingshot 10 of the present invention is the ability of the device to be detected by metal detectors at airports and other locations. It is relatively easy to design a plastic slingshot with no metal parts, or with only a few small metal parts, which easily can go undetected by metal detectors. However, as shown in
Self-Centering, Open-Pocket Pouch
The present invention includes a self-centering, open-pocket pouch 72, which may be used in conjunction with the collapsible locking slingshot described above, or with prior art slingshots. As shown in
The pouch 72 includes a centered pouch section 85, which is designed with two integrated exit ports 86a and 86b, one on each side of the centered pouch section 85 joined by a central flexing live-hinge 88 (other embodiments could include multiple live-hinge configurations). The ports 86a and 86b permit the ammunition to exit the centered pouch section 85 without making contact against the sides of the pouch by allowing air to enter the pouch and expand the pouch outward, away from the ammunition (much like a parachute opening). The centered pouch section 85 is molded substantially flat, which helps it open along with the air pressure. Reduction or elimination of side pouch contact dramatically improves shot accuracy since any contact along the sides will either deflect the ammunition path or apply spin to the ammunition (typically a ball, pellet, or multiple pellets) causing it to curve much the same way a pitcher applies spin to a baseball to make it curve in its path. The ports 86a and 86b can be elliptical in shape, extremely elongated elliptical in shape, or can be empty of material as shown in
However, regardless of the shape of the ports 86a and 86b, the design of pouch 72 takes advantage of the user's need to grip the pouch during the firing process to automatically center the ammunition within it. By necessity, a user's fingers will pinch the forward opening of centered pouch section 85 closed during use, since the user must grip the pouch in front of the ammunition in order to hold the pouch during the firing process. This gripping process, in conjunction with the radii in the rear section of centered pouch section 85, provides a nesting area for the ammunition during the launch phase. This nesting area cradles the ammunition in a generally centered configuration within the pouch. Because it is centered within the centered pouch section 85, upon release the ammunition is less likely to contact either side of the pouch and, therefore, is less likely to be deflected. This results in a more accurate and predictable shot.
The pouch 72 also includes a pair of ends 90, each an aperture 92 to permit the band 60 to slip through the apertures 92 and allow the pouch 72 to be used with the band 60.
Dual-Tapered Band
The present invention may also include a uniquely-engineering dual-tapered band 96, as shown in
The dual-tapered band 96 of the present invention has a unique double-taper. By tapering at both ends of the band 96, the pouch end 98 and the arm end 100, the thinnest area 102 of the band (the engineered failure point) is located away from the pouch, but towards the pouch end 98. Thus, the band flex is focused away from the pouch and over a greater area, decreasing band wear yet maintaining virtually all of the speed and smoothness of pull associated with tapered bands.
From the foregoing and as mentioned above, it will be observed that numerous variations and modifications may be effected without departing from the spirit and scope of the novel concept of the invention. It is to be understood that no limitation with respect to the specific methods and apparatus illustrated herein is intended or should be inferred. It is, of course, intended to cover by the appended claims all such modifications as fall within the scope of the claims.
This application is a continuation of U.S. application Ser. No. 12/343,978, filed on Dec. 24, 2008, which is a divisional of U.S. application Ser. No. 11/302,792, filed Dec. 14, 2005, now issued as U.S. Pat. No. 7,484,505 on Feb. 3, 2009, which claims the benefit of U.S. Provisional Application No. 60/638,547, filed Dec. 22, 2004.
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Number | Date | Country | |
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20100300419 A1 | Dec 2010 | US |
Number | Date | Country | |
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60638547 | Dec 2004 | US |
Number | Date | Country | |
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Parent | 11302792 | Dec 2005 | US |
Child | 12343978 | US |
Number | Date | Country | |
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Parent | 12343978 | Dec 2008 | US |
Child | 12849644 | US |