Tethered hand toy

Abstract

A skill toy that is juggled, spun, and flipped in one hand or between both hands. The skill toy has two subassemblies that each contains a rounded translucent shell. The translucent shell surrounds an internal illumination unit, wherein the rounded translucent shell has a maximum diameter of under two inches. The illumination units are motion activated and contain lights. A tether joins the subassemblies together. The tether can be selectively attached to, and detached from, the two subassemblies. The tether has a length of between four inches and six inches, so it is just long enough to span the back of a hand.

Claims

1. A toy assembly comprising: two subassemblies that each contain a rounded translucent shell, wherein each said rounded translucent shell has a maximum diameter of under two inches; an illumination unit disposed within each said rounded translucent shell for internally illuminating each said rounded translucent shell; a receptacle that extends into each said rounded translucent shell; a tether that can selectively attach to, and detach from, said subassemblies, said tether having a first end and an opposite second end, wherein said tether has a length between said first end and said second end that is between four inches and six inches; a first connector at said first end of said tether; and a second connector at said second end of said tether, wherein said first connector and said second connector are identical, and wherein said first connector and said second connector are sized to pass into either said receptacle on said subassemblies and engage said receptacle with an interference fit wherein friction keeps said first connector and said second connector engaged with each said receptacle until selectively pulled out of each said receptacle.

2. The toy assembly according to claim 1, wherein said internal illumination unit includes a battery, a logic circuit, and at least one LED.

3. The toy assembly according to claim 2, wherein said internal illumination unit contains a motion activator that activates said at least one LED when said internal illumination unit experiences motion.

4. The toy assembly according to claim 3, wherein said logic circuit causes said at least one LED to remain active for a predetermined period of time after said motion.

5. The toy assembly according to claim 1, wherein said translucent shell is made of an elastomeric material.

6. The toy assembly according to claim 1, wherein said tether is configured as a flat ribbon.

7. A toy assembly comprising: a first translucent ball; a first receptacle extending into said first translucent ball; a second translucent ball; a second receptacle extending into said translucent ball; a ribbon tether having a first end and an opposite second end that can selectively attach to, and detach from, said first translucent ball and said second translucent ball, wherein said first end terminates with a first connector that is received within said first receptacle and secured with an interference fit where friction keeps said first connector engaged with said first receptacle until selectively pulled out of said first receptacle, and wherein said second end terminates with a second connector that is received within said second receptacle and secured with an interference fit, where friction keeps said second connector engaged with said second receptacle until selectively pulled out of said second receptacle, and wherein said ribbon tether has a length of between two inches and four inches between said first connector and said second connector.

8. The toy assembly according to claim 7, wherein said first translucent ball and said second translucent ball each have a diameter of between one-half inch and two inches.

9. The toy assembly according to claim 7 further including internal illumination units disposed within said first translucent ball and said second translucent ball for internally illuminating said first translucent ball and said second translucent ball.

10. The toy assembly according to claim 9, wherein each of said internal illumination units includes a battery, a logic circuit, and at least one LED.

11. The toy assembly according to claim 10, wherein each of said internal illumination units contains a motion activator that activates said at least one LED when said internal illumination units experience motion.

12. The toy assembly according to claim 10, wherein said logic circuit causes said at least one LED to remain active for a predetermined period of time after said motion.

13. The toy assembly according to claim 7, wherein both said first translucent ball and said second translucent ball have elastomeric shells.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) 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:

(2) FIG. 1 is a perspective view of an exemplary embodiment of a toy assembly;

(3) FIG. 2 is a combined cross-section and schematic showing the components within a ball-shaped subassembly of the toy assembly;

(4) FIG. 3 shows the toy assembly in conjunction with a user's hand to illustrate the importance of length and size in proportion to the user's hand;

(5) FIG. 4 shows the toy assembly in a first position of a performed skill manipulation;

(6) FIG. 5 shows the toy assembly in a second position of a performed skill manipulation;

(7) FIG. 6 shows the toy assembly in a third position of a performed skill manipulation;

(8) FIG. 7 shows the toy assembly in a fourth position of a performed skill manipulation; and

(9) FIG. 8 shows the toy assembly in a fifth position of a performed skill manipulation.

DETAILED DESCRIPTION OF THE DRAWINGS

(10) Although the present invention toy assembly can be embodied in many ways, only one embodiment of the present invention is illustrated and described. The exemplary embodiment is 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.

(11) Referring to FIG. 1 and FIG. 2, a toy assembly 10 is shown. The toy assembly 10 has two ball-shaped subassemblies 12 that are joined together by a flexible tether 14. Each of the ball-shaped subassemblies 12 preferably has an external diameter D1 of between 0.5 inches and 2.0 inches. The flexible tether 14 has a preferred length of between four inches and six inches. The importance of these dimension ranges is later explained.

(12) Each of the ball-shaped subassemblies 12 has a spherical shell 16. The spherical shell 16 is preferably made of a translucent elastomeric material. The elastomeric material has a high durometer, so as to provide the spherical shell 16 with a high resiliency and the ability to rebound well when impacted against a hard surface. Accordingly, it will be understood that the ball-shaped subassemblies 12 will bounce when dropped against a hard surface. Likewise, they will bounce against each other if the two ball-shaped subassemblies 12 collide while being manipulated.

(13) An electronic unit 18 is disposed within each spherical shell 16. Each electronic unit 18 consists of a small circuit board 20 that supports a battery 22, a switch 24, a logic circuit 26 and at least one LED 28. The switch 24 is preferably an accelerometer switch or another such switch that can sense when the circuit board 20 is experiencing physical movement. The logic circuit 26 turns the LEDs 28 on for a predetermined period of time, such as a few seconds, each time movement is detected. Once the movement stops and the predetermined period of time for activation has expired, the logic circuit 26 turns the LEDs 28 off.

(14) The LEDs 28 are bright enough to shine light through the translucent material of the spherical shell 16. As such, the spherical shell 16 appears to be internally illuminated when it experiences movement. The circuit board 20 can flash or sequence the lighting of the LEDs 28 when the LEDs 28 are activated, therein producing changing light patterns in the internal illumination of the ball-shaped subassemblies 12.

(15) Each of the ball-shaped subassemblies 12 also includes a receptacle 30. The receptacle 30 is sized to receive and engage a connector 32, which is used to terminate the tether 14. The tether 14 can be a length of string, but is preferably a length of flat woven ribbon, like that of a sneaker shoelace. A flat ribbon adds a level of comfort to the toy assembly 10, as is later explained. A tether 14 of flat ribbon also provides a widened surface for a manufacturer's graphics.

(16) The tether 14 has two free ends 34, 36. The ends 34, 36 of the tether 14 are terminated with connectors 32. The connectors 32 at either end 34, 36 of the tether 14 are identical. The connectors 32 are dimensioned and sized to engage the receptacles 30 formed into each of the ball-shaped subassemblies 12. The connectors 32 preferably engage the receptacles 30 with an interference fit, wherein friction keeps the connectors 32 engaged within the receptacles 30. Releasable mechanical features, such as threading or a tab lock can also be used. Regardless, it will be understood that each ball-shaped subassembly 12 will remain attached to the tether 14 and will not inadvertently separate. However, a user can detach each of the ball-shaped subassemblies 12 from the tether 14 when desired.

(17) Referring to FIG. 3 in conjunction with FIG. 1 and FIG. 2, it will be understood that the toy assembly 10 is sized and dimensioned to be a skill game that is held in one hand and passed from hand to hand. The ball shaped subassemblies 12 are kept in a size range so that both of the ball-shaped subassemblies 12 can be held in the palm of the same hand by a user's thumb. This size range corresponds to a maximum diameter D1 on the ball-shaped assemblies 12 of between 0.5 inches and 2.0 inches. The length L1 of the tether 14 is held in a size range that is just long enough so it can span the back of the hand from one ball-shaped subassembly 12 to the other as both ball-shaped subassemblies 12 are being held in the palm of the same hand. This size range is between four inches and six inches.

(18) With the size of the ball-shaped subassemblies 12 and the length of the tether 14 described, a person can perform a variety of tricks with the toy assembly 10. By way of example, one of the tricks is called a roundabout. To perform a roundabout, a user holds the toy assembly 10 in one hand with a first of the ball-shaped subassemblies 12A in the palm under the ring finger and a second of the ball-shaped subassemblies 12b pinched between the thumb and forefinger. See FIG. 4. The second of the ball-shaped subassemblies 12B is released as the hand is moved in a clockwise direction.

(19) This causes the second of the ball-shaped subassemblies 12b to rotate behind the hand. See FIG. 5 and eventually rotate under the pinky finger and up over the palm. The user then allows the tether 14 to rotate back over the thumb, where the second of the ball-shaped subassemblies 12 can again be caught between the thumb and forefinger. See FIG. 6.

(20) This can end the trick. However, the tether 14 is taut and can transfer the energy of momentum to the first of the ball-shaped subassemblies 12A. The pinky finger can be bent forward to release the first of the ball shaped subassemblies 12A. The first of the ball-shaped subassemblies 12A then uses the momentum to rotate away from the palm and up over the forefinger to the back of the hand. See FIG. 7. The pinky finger can then be extended to catch the tether 14 between the pinky finger and the ring finger as it rotates around the back of the hand. See FIG. 8 The first of the ball-shaped subassemblies 12A is then caught under the ring finger and returns to the original position of FIG. 4.

(21) It will be understood that the size of the ball-shaped subassemblies 12 and the length of the tether 14 between the ball-shaped subassemblies 12 is critical to the ability to perform a maneuver such as is described between FIG. 4 and FIG. 8. The ball-shaped assemblies 12 must be large and heavy enough to swing the tether 14 but small enough to be held in place by a finger over the palm. The tether 14 must be just long enough to enable the tether 14 to wrap around the back of one's hand. If the tether is too long or too short, it will over-wrap or under-wrap. Either way, it will not position one of the ball-shaped assemblies over the palm where it can be grasped between a finger and the palm.

(22) Since many of the tricks involve swinging and wrapping the tether 14 around the hand, a tether 14 with a flat profile is preferred. A tether 14 with a flat profile prevents the tether 14 from rolling along a finger or the edge of the hand. A tether 14 with a flat profile also inhibits the tether 14 from cutting into the hand should the tether 14 come into contact with skin while taut.

(23) 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 ball-shaped subassemblies can be made with an oblong shape or a pear shape as a matter of design choice. All such embodiments are intended to be included within the scope of the present invention as defined by the claims.