This invention relates broadly to a method of creating a dynamic toy and, more specifically to a toy including a gyroscopic wheel providing inertial energy for the movement and stabilization of the toy when in motion.
Conventional toys using a gyroscopic component for providing energy to impart movement typically also include a reduction gearbox between the gyroscope and two drive wheels. This configuration results in a relatively complex drive system that may be subject to jamming, or gear slippage.
What is needed is a toy configuration in which a gyroscopic component may be utilized without a gearbox, in which toy movement may mimic actions of a top, and in which the toy may be used as a gyroscope.
In one aspect of the present invention, an inertial dynamic toy comprises: an annular housing having a circumferential groove; a flywheel mounted to a flywheel support axle, the flywheel support axle configured to be retained inside the annular housing; and an outrigger support frame releasably attached to the annular housing.
In another aspect of the present invention, a method of imparting dynamic action to a toy comprises: providing a flywheel mounted to a flywheel support axle; securing the flywheel support axle to an annular housing such that the flywheel freely rotates along an axis of rotation coincident with the flywheel support axle; and attaching an outrigger support frame to the annular housing such that the flywheel and the outrigger support frame provide two-point support to the annular housing.
These and other features and advantages of the present invention will be more fully understood from the following detailed description with reference to the accompanying drawings.
Alternatively, the inside surface 26 of the annular housing 16 may include raised areas (not shown) that fit into recesses (not shown) in the corresponding ends 22, 24 of the flywheel support axle 14, for example, so as to provide mechanical support. Either configuration will function to fix the flywheel support axle 14 in a predetermined position within the annular housing 16, while allowing the flywheel 12 to rotate freely with an axis of rotation coincident with the longitudinal axis of the flywheel support axle 14.
The annular housing 16 may include a circumferential groove 28 having a substantially semicircular cross-sectional shape, as shown in
The annular housing 16 may be supported, when placed on a surface, by means of an outrigger support frame 30 having a shape that generally resembles a figure eight, a butterfly, or a bowtie. The outrigger support frame 30 may include: (i) a first C-shaped fan-like section 32, (ii) a second C-shaped fan-like section 34, (iii) a first central curved section 36 attached to ends of the two C-shaped fan-like sections, and (iv) a second central curved section 38 attached to ends of the two C-shaped fan-like sections.
The first C-shaped fan-like section 32, the second C-shaped fan-like section 34, the first central curved section 36, and the second central curved section 38 may be formed from a single piece of rod or wire material to produce a unitary support component. Alternatively, the first C-shaped fan-like section 32, the second C-shaped fan-like section 34, the first central curved section 36, and the second central curved section 38 may comprise separate parts mechanically coupled together into an assembly using fasteners, brazing, soldering, or bonding, for example, with a butt joint or a lap joint configuration.
Either support configuration described above provides for a unitary wire-like component having the figure eight, butterfly, or bowtie shape. In an exemplary embodiment, the outrigger support frame 30 may comprise a heavy-gauge wire, or a plastic material, of from 1.0 mm to about 3.0 mm in diameter. The material for the outrigger support frame 30 is selected to provide a spring-like retention of the outrigger support frame 30 to the annular housing 16 without deformation, and also allow the annular housing 16 to be rotated within the outrigger support frame. 30.
Accordingly, the annular housing 16 may be removed from the outrigger support frame 30 by forcing the first central curved section 36 away from the second central curved section 38 such that the distance between the first central curved section 36 and the second central curved section 38 becomes larger than the diameter of the annular housing 16. By reversing the process, the first central curved section 36 and the second central curved section 38 may be placed back into the circumferential groove 28 and thus reassemble the inertial dynamic toy 10.
As can be appreciated by one skilled in the art, the flywheel 12 may perform three discrete functions. First, the flywheel 12 may function as a conventional wheel when the inertial dynamic toy 10 is moved across the support surface. Second, the flywheel 12 may provide physical support for the inertial dynamic toy 10 when at rest or otherwise in motion. Third, the flywheel 12 may function as a dynamic component in a gyroscope.
The flywheel 12 may function to convert the inertial dynamic toy 10 into a gyroscope after a user has placed the flywheel into a state of rotation by the impartation of a tangential force, or a push across the support surface. The inertial dynamic toy 10 is placed into an inverted orientation such that the inertial dynamic toy 10 rests on the dome cover 18. When the dome cover 18 is shaped as a hemisphere, as shown in the illustration, the inertial dynamic toy can spin about, or otherwise oscillate, depending upon the orientation of the inertial dynamic toy 10 when set down onto the support surface. Accordingly, a geometrical dome cover shape different from a hemisphere, such as a polygonal shape, can be used as an enclosure for the annular housing 16, provided that the spinning action of the flywheel 12 is not impeded by the dome cover. When the dome cover 18 has a polygonal shape (not shown), the inertial dynamic toy 10 may exhibit movements that differ from a configuration using a hemispherical dome cover 18.
As seen in the front view of
The two central curved sections 36, 38 are sized to fit into, and be retained within, the circumferential groove 18. The outrigger support frame 30 may be fabricated from a flexible rod-like material, such as a soft metal or a flexible plastic, so as to insure that the two central curved sections 36, 38 are held in place in the circumferential groove 18 by compressive, spring-like forces provided by the first C-shaped fan-like section 32 and the second C-shaped fan-like section 34.
As shown in
In an exemplary embodiment, the flywheel 12 may have a diameter “D” of from about 30 mm to about 40 mm, and the outrigger support frame 30 may have an outer dimension “B” of from about 120 mm to about 200 mm. The resulting clearance between the outrigger support frame 30 and the support surface 40, indicated by dimension “G,” may range from about 5 mm to about 0.5×D. The annular housing 16 may have an outside diameter “C” of from about 45 mm to about 70 mm.
It can be appreciated that the annular housing 16 can be rotated relative to the outrigger support frame 30, as indicated by arrow “F.” This feature allows a user of the inertial dynamic toy 10 to vary the angular position of the flywheel 12 in the outrigger support frame 30, so as to produce various different modes of rocking motions of the inertial dynamic toy 10, such as side-to-side or front-to-back, when the flywheel 12 is spinning.
In an exemplary embodiment, shown in
It should be understood that the present invention is not limited to the two patterns shown, and that other types and styles of patterns may be used to cover the first C-shaped fan-like section 32 and the second C-shaped fan-like section 34. The particular pattern used is limited only by the imagination of the designer of the inertial dynamic toy 10.
In an exemplary embodiment, an inertial dynamic toy 10 may comprise an annular housing assembly 50, shown in
A flywheel 60 may be retained on a support axle 62. The flywheel 60 may have an outside diameter of approximately 30 mm and a thickness of about 10 mm. The support axle 62 may have a diameter of approximately 3 mm and a length of approximately 44 mm. The flywheel 60 may be loosely retained on the support axle 62 such that the flywheel 60 may rotate even if the support axle 62 is fixed in place. In an exemplary material, the flywheel 60 may be fabricated from a metal such as brass.
As shown in
In an exemplary embodiment, shown in
Many of the specific details of certain embodiments of the invention are set forth in the above description and related drawings to provide a thorough understanding of such embodiments. One skilled in the art will understand, however, that the present invention may be practiced without several of the details described in the above description. Moreover, in the description, it is understood that the figures related to the various embodiments are not to be interpreted as conveying any specific or relative physical dimension.
The present Application is a Divisional of U.S. Pat. No. 8,870,621.
Number | Date | Country | |
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Parent | 13461568 | May 2012 | US |
Child | 14525492 | US |