1. Field of the Invention
In general, the present invention relates to toy objects that are spring biased in an expanded configuration, yet can be temporarily configured into a collapsed configuration. More particularly, the present invention relates to thrown toy objects, such as balls, that can be temporarily pressed into a collapsed configuration, wherein the thrown toy pops back into an expanded configuration a short time later.
2. Description of the Prior Art
The prior art is replete with various types of toys that are intended to be thrown. Prominent among such toys are balls and discs. It therefore is not surprising that toy manufacturers eventually combined the features of both a ball and a disc into a single throwing toy.
It is for this reason that collapsible ball throwing toys were first introduced into the toy market. Collapsible ball throwing toys are balls, or similar spherically shaped objects, that are comprised of an upper hemisphere and a lower hemisphere. The upper hemisphere and the lower hemisphere are joined together with hinged connections along a common equatorial joint. Due to the hinged connections between the upper hemisphere and the lower hemisphere, the upper and lower hemispheres of the ball can be collapsed flat against each other. When the upper and the lower hemispheres of the toy are collapsed against each other, the toy has the general configuration of a disc. Accordingly, the collapsible ball throwing toy can be configured either as a ball or as a disc, depending upon whether or not the toy is compressed.
As the upper and lower hemispheres of the toy are collapsed into a flat configuration, the diameters of the hemispheres expand. To accommodate this expansion, the upper and lower hemispheres of the toy are slotted. When the toy is fully expanded into its ball shape, the slots are closed and the toy has a continuous external surface. However, when the toy is flattened into a disc, the slots open and expand, giving the disc a daisy configuration. A typical daisy configuration of a collapsible ball throwing toy can be seen by referencing U.S. Pat. No. Des 434,457 to Goldman, entitled Collapsible Toy and U.S. Pat. No. 6,863,588 to Chu, entitled Collapsible Throwing Toy And Its Associated Method Of Manufacture.
In the prior art, collapsible ball throwing toys typically have some sort of biasing element that biases the collapsible ball throwing toy into its expanded, ball-like configuration. For example, in U.S. Pat. No. 5,797,815 to Goldman, entitled Pop-Open Throwing Toy With Controllable Opening Delay And Method Of Operating Same, a collapsible ball throwing toy is shown that has an internal coil spring. The coil spring biases apart the upper and lower hemispheres of the toy. The collapsible ball throwing toy can be temporarily configured like a disc by compressing the internal coil spring and resisting the bias of the coil spring with a momentary suction cup connection between the upper and lower hemispheres. As soon as the momentary suction cup connection fails, the internal coil spring pops the collapsible ball throwing toy back into its expanded ball-like configuration.
In U.S. Pat. No. 4,955,841 to Pastrano, entitled Disc-Shaped Throwing Toy, a collapsible ball throwing toy is disclosed. The collapsible ball throwing toy is shaped like a polyhedron. The collapsible ball throwing toy has an upper and lower hemisphere joined with a hinged connection along an equatorial joint. When compressed, the hemispheres flatten along lines in the polyhedral pattern and expand at the equatorial joint. Due to the hinged connection at the equatorial joint, the upper and lower hemispheres can fold flat against each other. However, once a compressing force is removed, the memory of the material used to make the polyhedral configuration causes both hemispheres to slowly return to their expanded shapes. As such, the collapsible ball throwing device can be flattened and thrown. After being thrown, the collapsible ball throwing device slowly returns to its expanded spherical shape. This prior art design, therefore, lacks the desired sudden transition between a collapsed condition and an expanded condition that other prior art versions of a collapsible ball throwing toy embody.
In the manufacturing of prior art collapsible ball throwing toys, one of the controlling costs is how to form the biasing mechanism that biases the toy into its expanded form. If a coil spring is used, there is the cost of the coil spring and the configurations needed to retain the coil spring. If the shell of the collapsible ball throwing toy is used as the biasing mechanism, a complicated shell configuration must be used that greatly increases the costs involved in tooling and assembling the toy. Furthermore, it is desirable that the collapsible ball throwing toy suddenly pop between its flat configuration and its expanded configuration. The collapsible ball throwing toy must therefore have a strong biasing mechanism and an equally strong temporary connecting mechanism that temporarily resists the biasing mechanism. Such connecting mechanisms also add significantly to the cost of manufacture.
Another disadvantage inherent in prior art designs is that when the collapsible ball throwing type is collapsed, it becomes disc shaped. However, the disc shape is not particularly aerodynamic. Furthermore, the disc shape lacks the air foil design that enables real toy flying discs, such as a FrisbeeĀ®, to fly well.
A need therefore exists for a collapsible throwing toy that can be modified in its construction so that it forms a more perfect airfoil shape when compressed. In this manner, the collapsible throwing toy can fly further and straighter than prior art configurations. This need is met by the present invention as described and claimed below.
The present invention is a toy assembly that is configurable between a ball shape and a disc shape. The toy assembly is biased into its ball shape, but can be temporarily compressed into a disc shape for throwing. When compressed into a disc shape, an air foil configuration is achieved that enables the toy assembly to achieve stable flight while traveling long distances.
The toy assembly has a first hub. A first plurality of body flaps radially extend from the first hub. The first plurality of body flaps are coupled to the first hub with a first set of hinge joints. The first hub and first plurality of body flaps create a first hemispherical subassembly.
The opposing second hemispherical subassembly is created in a similar manner. A second hub is provided. A second plurality of body flaps radially extend from the second hub. The second plurality of body flaps are coupled to the second hub with a second set of hinge joints.
The two hemispherical subassemblies do not directly interconnect. Rather a resilient ring is provided. The resilient ring is engaged by all of the first plurality of body flaps and all of the second plurality of body flaps. The resilient ring binds the two hemispherical subassemblies together and biases the first plurality of body flaps and the second plurality of body flaps into a ball shape.
Inside the toy assembly, a temporary connector is coupled to the first hub and to the second hub. The temporary connector temporarily interconnects the first hub and the second hub for a period of time after the first hub and the second hub are pressed together. When the first hub and the second hub are pressed together, the toy assembly embodies its disc shape. When the temporary connector releases, the toy assembly pops back suddenly into its ball shape.
For a better understanding of the present invention, reference is made to the following description of an exemplary embodiment thereof, considered in conjunction with the accompanying drawings, in which:
Although the present invention can be embodied into many shapes, such as the elongated shape of a football, only one exemplary embodiment is illustrated. The exemplary embodiment shows the present invention embodied as a round ball. This embodiment is selected to represent one of the best modes contemplated for the invention. However, the embodiment is merely exemplary and should not be considered a limitation on the claims.
Referring to
The hemispherical subassemblies 12, 14 both are generally hemispherical in shape. However, the first hemispherical subassembly 12, has a slightly larger radius of curvature than does the second hemispherical subassembly 14. As such, when assembled together, the first hemispherical subassembly 12 overlaps sections of the second hemispherical subassembly 14.
The first hemispherical subassembly 12 has a first hub 20. The first hub 20 is curved and has a multi-sided peripheral edge 22 that follows a polygonal shape. A plurality of long flaps 24 are attached to the peripheral edge 22 of the first hub 20, wherein one of the long flaps 24 is attached to straight sections between salient points. The long flaps 24 are attached to the straight sections along the peripheral edge 22 at hinged connections 26. The hinge connections 26 can be mechanical hinges. However, in the preferred embodiment, the first hub 20 and the long flaps 24 are preferably molded together as an integral piece. In such a manufacturing scenario, the hinged connections 26 are living hinges created by thinned sections of the molded plastic.
Likewise, the second hemispherical subassembly 14 has a second hub 30. The second hub 30 is curved and has a multi-sided peripheral edge 32 that follows a polygonal shape. A plurality of short flaps 34 are attached to the peripheral edge 32 of the second hub 30, wherein one of the short flaps 34 is attached to straight sections between salient points. The short flaps 34 are attached to the straight sections along the peripheral edge 32 at hinge connections 36. The hinge connections 36 can be mechanical hinges. However, in the preferred embodiment, the second hub 30 and the short flaps 34 are preferably molded together as an integral piece. In such a manufacturing scenario, the hinged connections 36 are living hinges created by thinned sections of the molded plastic.
The long flaps 24 and the short flaps 34 are both curved. The curved length of the long flaps 24 is longer than the curved length of the short flaps 34. There are spaces 28 between the various long flaps 24. Likewise, there are spaces 38 between the various short flaps 34. When in its spherical configuration, the long flaps 24 overlap the short flaps 34, wherein the long flaps 24 are aligned over the spaces 38 between the short flaps 34. As will later be explained in more detail, both the long flaps 24 and the short flaps 34 engage the same resilient ring 16. It is the resilient ring 16 that biases the long flaps 24 and the short flaps 34 into the spherical configuration of the toy assembly shown in
Referring to
Each long flap 24 has an overhang section 44 that extends from the hook structure 40 to the free end 25 of the long flap 24. The hook structure 40 is sized and shaped to receive and retain the resilient ring 16 that extends near the equator within the toy assembly 10.
Referring to
Referring to
Referring to
To convert the toy assembly from its spherical shaped configuration into its disc shaped configuration, a person compresses the first hub 20 and the second hub 30 toward each other. If the applied force overcomes the spring bias of the resilient ring 16, then the toy assembly 10 collapses. As the first hub 20 and the second hub 30 are compressed toward each other, the long flaps 24 and the short flaps 34 flare out in a radial pattern from the hubs 20, 30. This expands the resilient ring 16. The bias force of the expanded resilient ring 16 acts in opposition to the expansion.
Referring to
A suction cup 54 and a flat plate 56 are provided. The suction plate 54 and the flat plate 56 are attached to the interior of the first hub 20 and the second hub 30 in any order. Accordingly, the suction cup 54 can extend inwardly from either the first hub 20 or the second hub 30. The flat plate 56 is coupled to the hub opposite the suction cup 54. In the shown embodiment, the suction cup 54 is attached to the first hub 20 and the flat plate 56 is attached to the second hub 30.
The toy assembly 10 can be flattened into a disc shape by compressing the first hub 20 toward the second hub 30. At the point of optimal compression, the suction cup 54 engages the flat plate 56 and adheres to the flat plate 56. Once the suction cup 54 engages the flat plate 56, the toy assembly 10 is temporarily held in its compressed disc shape. The compressed toy assembly 10 creates a flying disc, as shown in
The resilient ring 16 resists the deformation of the toy assembly 10 into the compressed disc shape. After a period of time, the connection between the suction cup 54 and the flat plate 56 releases. Upon the release, the resilient ring 16 causes the toy assembly 10 to immediately pop back into its original spherical shape. The period of time that the suction cup 54 remains in connection with the flat plate 56 varies depending upon certain factors. The factors include the force with which the suction cup 54 was pressed against the flat plate 56, the cleanliness of the suction cup 54 and the flat plate 56, ambient temperature, ambient humidity, and the latent resiliency of the resilient ring 16. Accordingly, the toy assembly 10 will remain in its disc shape for varying periods of time each time the toy assembly 10 is compressed.
To utilize the toy assembly 10, a user compresses the first hub 20 toward the second hub 30. This causes the toy assembly 10 to change from its ball shaped configuration to its disc shaped configuration. Once compressed, the temporary connector 52 within the toy assembly 10 keeps the toy assembly 10 in its disc shaped configuration for a short period of time. This enables the toy assembly 10 to be thrown like a flying disc. After a short period of time, the temporary connector releases and the toy assembly 10 pops back into its ball shaped configuration. It can be played with as a ball until again being compressed into a disc.
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 of the invention using functionally equivalent components. All such variations, modifications, and alternate embodiments are intended to be included within the scope of the present invention.
Number | Name | Date | Kind |
---|---|---|---|
2952460 | Ellis | Sep 1960 | A |
2968121 | Pearson, Jr. et al. | Jan 1961 | A |
3113396 | Collins | Dec 1963 | A |
3218071 | Eugene | Nov 1965 | A |
3758985 | Heisler | Sep 1973 | A |
4135325 | Lehman | Jan 1979 | A |
4196882 | Rognon | Apr 1980 | A |
4607875 | McGirr | Aug 1986 | A |
4790714 | Schnapp | Dec 1988 | A |
4794024 | Crowell et al. | Dec 1988 | A |
4955841 | Pastrano | Sep 1990 | A |
5090569 | Nissen et al. | Feb 1992 | A |
5096751 | Duchek | Mar 1992 | A |
5123869 | Schipmann | Jun 1992 | A |
5263760 | Sohol | Nov 1993 | A |
5381990 | Belokin et al. | Jan 1995 | A |
5511752 | Trethewey | Apr 1996 | A |
5797815 | Goldman et al. | Aug 1998 | A |
D434457 | Goldman et al. | Nov 2000 | S |
D441107 | Okuda | Apr 2001 | S |
6863588 | Chu | Mar 2005 | B1 |
6896577 | Feng | May 2005 | B1 |
Number | Date | Country |
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1992391 | Nov 2008 | EP |
Number | Date | Country | |
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20160346628 A1 | Dec 2016 | US |
Number | Date | Country | |
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62167721 | May 2015 | US |