1. Field of the Invention
In general, the present invention relates to toy launchers, such as slingshots that are used to launch a toy projectile into flight.
2. Prior Art Description
Slingshots and similar launchers that are designed for child's play have existed throughout recorded history. In the modern era, toy slingshots typically have a plastic molded handle and an elastic string. A pocket is present on the elastic string. Objects are launched by placing the object in the pocket, pulling the pocket back against the bias of the elastic string, and releasing the pocket.
Due to the nature of its design, any slingshot, including toy slingshots, are capable of launching any object that is placed in the pocket. Although a toy slingshot may be sold with safety projectiles, a child can easily launch a small stone with equal ease. It will therefore be understood that even toy slingshots can cause injury if used in an unwise fashion.
Another problem with toy slingshots is their failure mode. If a slingshot is drawn beyond its limit, then the string of the slingshot may break. Depending upon where the breakage occurs, the broken string may fly back toward the person holding the slingshot as the stored energy is accidentally released. Since a slingshot is often held in front of the face, the whip-back of a broken string can easily cause injury to the eye.
A need therefore exists for a toy slingshot design that enables the toy slingshot only to shoot the safety projectiles that are packaged with the toy slingshot. Furthermore, a need exists for a slingshot design that eliminates the dangers of string failure to a child who may overdraw the slingshot. This need is met by the present invention as described and claimed below.
The present invention is a toy projectile launcher and safety projectile combination, wherein the launcher sets the safety projectile into flight. The toy launcher can only launch the safety projectile. The toy launcher has a body with a first arm, a second arm, and a central region that separates the first arm and the second arm. Both the first arm and the second arm contain spring-loaded joints that enable parts of both arms to twist and reorient when stressed.
A first elastomeric element extends laterally from the first arm section into the central region. The first elastomeric element has a first free end that is supported as a cantilever. Likewise, a second elastomeric element extends laterally from the second arm section into the central region. The second elastomeric element has a second free end that is also supported as a cantilever.
A safely projectile is provided. The safety projectile has a first slotted channel that is accessible through a first open end and a second slotted channel that is accessible through a second open end. The safety projectile temporarily attaches to the first elastomeric element and the second elastomeric element during launching by having the first slotted channel receive the first free end of the first elastomeric element and having the second slotted channel receive the second free end of the second elastomeric element.
The safety projectile is then pulled back and released. The needed engagement of the two slotted channels of the projectile with the two elastomeric elements of the slingshot ensure that only authorized, safety projectiles can be launched.
For a better understanding of the present invention, reference is made to the following description of am exemplary embodiment thereof, considered in conjunction with the accompanying drawings, in which:
Although the present invention toy launching system can be embodied in many different projectile configurations, such as a box, a crossbow, or a pistol, the exemplary embodiment selected shows a slingshot. The exemplary embodiment has been selected in order to set forth one of the best modes contemplated for the invention. The illustrated embodiment, however, is merely exemplary and should not be considered a limitation when interpreting the scope of the appended claims.
Referring to
Each of the arm assemblies 16, 18 include a lower static base 21 and an upper moving post 23. The static bases 21 of both arm assemblies 16, 18 are molded together as a single support piece 25. The support piece 25 is attached to the handle 14. Each moving post 23 is attached to the support piece 25 at a twist joint 31. A pivot pin 33 extends downwardly from the bottom of each of the moving posts 23. The pivot pins 33 engage torsion springs 35 that are mounted inside the static base 21. The torsion springs 35 apply a spring bias to the pivot pins 33 that bias the moving posts 23 into the unloaded orientation shown in
The top of each moving post 23 terminates with an enlarged relief 22. The purpose of the large reliefs 22 is later explained in detail.
Two elastomeric elements 24 are provided. The elastomeric elements 24 can be solid strands of elastomeric material or segments of elastomeric tubing. Each of the elastomeric elements 24 extends straight between an anchor end 26 and a free end 28. Both the anchor end 26 and the free end 28 are terminated with an enlarged bead 27, 29 that is permanently affixed to the elastomeric element 24. The beads 27, 29 are preferably made of a hard plastic so that the beads 27, 29 do not deform when stressed by the operation of the slingshot launcher 10. Conversely, the elastomeric elements 24 are highly elastomeric and are capable of elastically expanding to at least three times their original length without tearing or breaking when stressed.
A segment of reinforcement tubing 30 is provided around each of the elastomeric elements 24. The reinforcement tubing 30 is thicker, tougher, and less elastic than the elastomeric elements 24. Although the reinforcement tubing 30 lay around sections of the elastomeric elements 24, the reinforcement tubing 30 is not bonded or otherwise attached to the material of the elastomeric elements 24.
An anchor port 32 is formed in each of the arms 16, 18 of the slingshot body 12 below the enlarged reliefs 22. The anchor ports 32 are sized to receive the anchor bead 27 at the anchor end 26 of the elastomeric elements 24. When the anchor bead 27 enters the anchor port 32, the anchor bead 27 becomes wedged in place and cannot move. This connects the anchor end 26 of each of the elastomeric elements 24 to the arms 16, 18 of the slingshot body 12.
Two plug elements 34, 36 are provided. Each of the plug elements 34, 36 defines a bottom slot 38 that turns ninety degrees. The plug elements 34, 36 pass into the enlarged reliefs 22 at the top of the arms 16, 18. The elastomeric elements 24 pass through the slots 38 in the plugs 34, 36. Consequently, the elastomeric elements 24 are bent ninety degrees as they extend through the bottom slot 38. As a result, the free end 28 of each elastomeric element 24 extends horizontally toward each other in the central region 17. As a result, both elastomeric elements 24 have free ends 28 that extend toward each other and terminate as cantilevered structures. The free end beads 29 at the ends of the elastomeric elements 24 are disposed a short distance apart.
The plug elements 34, 36 also engage one end of each segment of the reinforcement tubing 30. The segments of reinforcement tubing 30 also extend horizontally toward each other as cantilevered structures. The support provided by the reinforcement tubing 30 helps prevent the elastomeric elements 24 from sagging under the force of gravity.
The plug elements 34, 36 are attached to the enlarged reliefs 22 using either adhesive and/or a mechanical fastener, such as the shown screw 39.
Referring to
Slotted channels 42 are formed in the safety projectiles 40. Each slotted channel 42 has only one open end 44. The open ends 44 of the two slotted channels 42 are spaced a predetermined distance apart. The distance between the open ends 44 of the slotted channels 42 are exactly the same as the distance between the beads 29 at the free ends 28 of the elastomeric elements 24. It will therefore be understood that the beads 29 at the free ends 28 of the elastomeric elements 24 can easily pass into the slotted channels 42 of the safety projectile 40 through the open ends 44 of the slotted channels 42.
Each of the slotted channels 42 are lined with a slotted hard plastic insert 46. The presence of the hard plastic insert 46 prevents the hard free end beads 29 of the elastomeric elements 24 from being pulled out of the slotted channel 42 through the soft material of the safety projectile 40.
Referring to
As the torque applied by the stretching of the elastomeric elements 24 overcomes the bias of the torsion springs 35, the moving posts 23 begin to turn into the orientation shown in
When the safety projectile 40 is released, the spring energy stored in the elastomeric elements 24 and the torsion springs 35 is simultaneously released. The slingshot launcher assembly 10 suddenly changes from the loaded configuration of
It will be understood that the elastomeric elements 24 of the slingshot launcher 10 can only engage a projectile that has the slotted channels 42 that are sized and spaced to receive the two beads 29 at the two free ends 28 of the elastomeric elements 24. Consequently, the present invention slingshot launcher 10 cannot launch a rock, marble, gumball, or anything else that is not specifically manufactured with the necessary slotted channels. A child having possession of the slingshot launcher 10 will therefore only be able to use the slingshot launcher 10 to launch the safety projectiles 40 provided with the slingshot launcher 10.
When the elastomeric elements 24 are stretched, they are most vulnerable to breakage. If one of the elastomeric elements 24 breaks, it is highly improbable that the second elastomeric element 24 would break at that precise moment. The unbroken elastomeric element 24 will, therefore, remain intact and will absorb much of the energy released by the broken elastomeric element. This prevents a broken elastomeric element from whipping back toward a user's face.
The slotted channels 42 within the safety projectile 40 have the same diameter as the projections 20 that extend outwardly from the slingshot body 12. This enables a projection 20 to pass into and engage the safety projectiles 40 with an interference fit. As a result, safety projectiles 40 that are not being used can be attached to the body 12 of the slingshot launcher 10 and held at the ready.
It will be understood that the embodiment of the present invention that is illustrated and described is merely exemplary and that a person skilled in the art can make many variations to that embodiment. For instance, the bow structure can have many different ornamental shapes. Likewise, the arrow projectiles can be configured as airplanes, rocket ships or any other flying projectile. All such embodiments are intended to be included within the scope of the present invention as defined by the claims.
This application is a continuation-in-part of U.S. patent application Ser. No. 13/225,438 filed Sep. 3, 2011.
Number | Name | Date | Kind |
---|---|---|---|
5279276 | Nagel et al. | Jan 1994 | A |
5282453 | Chia | Feb 1994 | A |
5657738 | Klundt | Aug 1997 | A |
6500042 | LaPointe | Dec 2002 | B1 |
8485168 | Walterscheid | Jul 2013 | B2 |
Number | Date | Country | |
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20130167819 A1 | Jul 2013 | US |
Number | Date | Country | |
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Parent | 13225438 | Sep 2011 | US |
Child | 13773615 | US |