The present invention relates to toys and game apparatuses and, more particularly, to toys and game apparatuses that a user may roll.
One of popular in-door activity games is bowling. In bowling, a user rolls a ball toward a number of pins, and the ball rolls a considerable distance along the bowling alley. Complicated and expensive equipment is required for a bowling game, as well as a specialized facility where users can play the game. Those factors prevent bowling from being played at home.
A variety of rolling toys for children are known. By way of example, U.S. Pat. No. 6,485,349 to Snyder and others discloses a rolling toy having a tubular assembly with a ball moving within a tubular assembly positioned inside the tubular assembly. When a user makes the toy rolling, audio and video signals are generated due to a motion sensor incorporated into body of the toy. U.S. Pat. No. 5,947,793 to Yamakawa provides a self-propelling rolling toy which is able to change the route of rolling movement if an obstacle is encountered by the toy. Both of the cited patents have a relatively complicated structure. Moreover, there is a need of rolling-type games, similar to bowling, that can be played at home.
The object of the present invention is to provide a new rolling toy which, when being thrown or rolled by a user, will roll on a horizontal support surface, for a certain distance and then stands up by itself. The rolling distance depends on a preliminarily adjustment to the rolling toy made by the user. The toy may be utilized for a completely new game.
One aspect of the invention provides a rolling toy having a primary roller and a secondary roller. The primary roller has a tubular-like member extending along a longitudinal axis thereof between left end and right end. The primary roller has at least one annular flange fixedly attached to the tubular-like member. The at least one annular flange is configured such that the primary roller is rollable on the at least one annular flange on a horizontal support surface. The tubular-like member has a substantially cylindrical interior surface. The secondary roller is sized to fit within the tubular-like member and is adapted for a rolling motion on the cylindrical interior surface when the longitudinal axis is orientated horizontally and the primary roller is in a rotational motion about the longitudinal axis.
As to another aspect of the invention, at least one of the following includes a helical guiding means: the tubular-like member and the secondary roller. The helical guiding means is/are configured for urging the secondary roller to move longitudinally toward the left end or the right end when the secondary roller is in the rolling motion on the substantially cylindrical interior surface of the tubular-like member.
As to a further aspect of the invention, configurations of the primary and secondary rollers and weights of the rollers are such that, as the primary roller is positioned having the longitudinal axis oriented horizontally, at least one of the following is satisfied: (a) a center of gravity of the rolling toy is located to the left of a leftmost annular flange of the at least one annular flange when the secondary roller is disposed on the substantially cylindrical interior surface in close proximity to the left end, (b) the center of gravity of the rolling toy is located to the right of a rightmost annular flange of the at least one annular flange when the secondary roller is disposed on the substantially cylindrical interior surface in close proximity to the right end, (c) a center of gravity of the primary roller is located to the left of a leftmost annular flange of the at least one annular flange, and (d) the center of gravity of the primary roller is located to the right of a rightmost annular flange of the at least one annular flange.
As to a further aspect of the invention, the tubular-like member includes a support area located on the leftmost or the rightmost portion thereof and configured such that the primary roller is positionable on the support area on the horizontal support surface, thereby, the tilting of the primary roller may result in the standing thereof on the horizontal support surface.
The preferred embodiments of the invention will hereinafter be described in conjunction with the appended drawings provided to illustrate and not to limit the invention, where like designations denote like elements, and in which:
Referring now to
The tubular-like member 108 has an opening 113 in the left end 110. In
The size, relative location and weight of the parts of the primary roller 104 are such that the center of gravity (COG) thereof is located in the position indicated by the cross 130: on the longitudinal axis A-A, close to an imaginary vertical plane 132 associated with the right annular flange 118. A light weight of the tubular-like member 108 and a heavy weight of the metal disk 114 define such location of the primary roller's COG.
A helical ridge 120 extends inwardly from a substantially cylindrical interior surface of the tubular-like member 108. The helical ridge 120 runs between the left end 110 and the right end 112. The helical ridge 120 forms a helical groove 122. As a way of example, the helical ridge 120 has a right hand helix; a pitch of the helix is marked in
The secondary roller 106, preferably, has a shape of a dumbbell. A user initially holds the primary roller 104 so that axis A-A is oriented horizontally, then he/she places the secondary roller 106 inside the tubular-like member 108 through the opening 113 so that the secondary roller lays freely on the helical groove 122.
When the primary roller 104 is positioned on the horizontal support surface 134 and the secondary roller 106 lays on the helical groove 122 in the vicinity of the left end 110, COG of the rolling toy 102 (defined by a relative position, configuration and weights of the primary and secondary rollers) is located at the position indicated by the cross 136, between annular flanges 116 and 118. With that, projection of the rolling toy's COG on the support surface 134 lies between points of contact of the annular flanges with the support surface. Thereby, the rolling toy is in an equilibrium state. (When the secondary roller is positioned in the middle section of the tubular-like member, COG of the rolling toy is still located between the annular flanges). On the other hand, when secondary roller 106 lays on the helical groove 122 in the vicinity of right end 112, COG of the rolling toy lies to the right of the plane 132 which forces the rolling toy to tilt (this will be described in detail further). For simplicity, we'll be using the wording “the secondary roller inside the primary roller” instead of “the secondary roller inside the tubular-like member of the primary roller”. It should be understood that shape of the secondary roller 106 can have a different than dumbbell; for instance, it can be shaped as a ball.
Four positions of the rolling toy 102 on the horizontal support surface are shown schematically in snapshots in
Consequently, the rightmost circular edge of the metal disk 114 touches the horizontal support surface 134; the point of contact is marked as 144 in the snapshot
Positions of the rolling toy 102, as they are seen from above, are illustrated in
A distance that the rolling toy rolls upon the support surface prior to standing up is, roughly:
Dist_Roll=3.14*Diam_flange*Num_Rvl (1),
where Diam_flange is the outer diameter of the left and right annular flanges and Num_Rvl is the number of revolutions of the primary roller. In order to achieve the longest distance of the rolling toy rolling, the user initially disposes the secondary roller 106 inside the primary roller 104 in a position closest to left end 110 (see
Dist_Roll_Max=3.14*Diam_flange*Num_Coils (2).
If the user places the secondary roller initially inside the primary roller 104 in a position closer to the right end, the distance of the rolling toy rolling is proportionally shorter than Dist_Roll_Max. For instance, if the initial position of the secondary roller is in the middle section of the primary roller then the rolling distance is twice shorter than Dist_Roll_Max.
Here is an example of the rolling toy design and dimensions. The helical ridge has ten coils. The pitch PP of the helix is 16 mm; a longitudinal length of the helix is 10*16 mm=160 mm. Outer diameter of the annular flanges is 130 mm. According to formula (2), distance Dist_Roll_Max is 4.1 m (about 13′). An inner diameter of the tubular-like member 108 is 50 mm. In general, according to our estimation, outer diameter of the annular flanges must be at least 25% larger than inner diameter of the tubular-like member.
When a user holds the primary roller 304 horizontally, he/she positions the secondary roller 306 on the interior ridges 320, close to the left end 310. When the primary roller rolls upon a support surface 334, the secondary roller 306 remains in the lowest position. Due to frictional engagement between the secondary roller and the interior ridges 320, the secondary roller rolls upon the interior ridges. Similar to the first embodiment, when the primary roller 304 rotates in the direction illustrated in
It should be understood that configuration of the primary and secondary rollers can be different than the configuration shown in
Here is an assessment of the rolling toy's dimensions according to the third embodiment. A maximal distance DL3 of the longitudinal movement of the secondary roller 306 inside the primary roller 304 during the rolling toy's rolling is roughly:
DL3=NR3*PS3*DP3/DS3,
where NR3 is a maximal number of revolutions of the primary roller 304; DP3 is the inner diameter of interior ridges 320 and DS3 is a diameter of the secondary roller's 306 cylindrical body. As an example: NR3 is equal to ten; the pitch PS3 is 10 mm; diameter DP3 is 50 mm and diameter DS3 is 30 mm. With that, the distance DL3 is 167 mm. Correspondingly, a full length of the primary 304 roller along the axis A3-A3 is about 220 mm.
When the primary roller 404 rotates in the direction illustrated in
DL4=NR4*(PP4−PS4*ID4/DS4),
here: NR4 is the number of revolutions of primary roller 404, PP4 is a pitch of the primary roller's helical ridge 420, PS4 is a pitch of the secondary roller's helical ridge 407, ID4 is an inner diameter of the primary roller's helical ridge 420, DS4 is a diameter of the secondary roller's cylindrical body.
With the specified configuration of the helixes and direction of the primary roller's rotation, the helical ridge 420 causes the longitudinal movement of the secondary roller 406 rightward, while the helical ridge 407 causes the longitudinal movement of the secondary roller 406 leftward. Thereby, a configuration of both rollers in which the “rightward-moving” component PP4 is slightly greater than the “leftward-moving” component PS4*ID4/DS4, provides a slow longitudinal movement of the secondary roller in the rightward direction. This provides for a longer distance of the rolling toy's rolling (more rotations) with a smaller number of coils of the helical ridge 420 and, correspondingly, smaller longitudinal size of the primary roller.
Configuration of the primary roller of the rolling toy can be different from those described in the previous embodiments. For instance,
It is should be understood that the rolling toy can be used when the secondary roller moves longitudinally in the direction from right to left, which is opposite to the direction in the embodiments described hereinabove. Such a mode of operation is illustrated in
The user rolls the rolling toy on the support surface 1134 such that the primary roller 1104 rotates clockwise, looking at it along its longitudinal axis from the left side (the rotation is opposite from the one shown in
When the primary roller 604 rolls upon a horizontal support surface as illustrated in the
It should be understood that in the “single annular flange” schema, a different configuration of the tubular-like member and the secondary roller can be utilized Similar to the second embodiment, the interior surface of the tubular-like member may have a helical ridge (rather than the spaced apart circular interior ridges), and the secondary roller may have circular ridges extending outwardly its body. Another option might be the “two helixes” schema as in the fourth embodiment of the invention.
It should be understood also that directions of the helixes in the all of embodiments described hereinabove were selected by way of example. For instance, in the first embodiment, the helical ridge has a right hand helix. Therefore, under the conditions illustrated in
It is also should be understood that shape, material and relative location of the parts of the rolling toy can be different from those described and illustrated hereinabove. For example, in the first embodiment, the secondary roller can have a spherical or semi-spherical shape. The tubular-like member can have, for instance, a shape of a barrel or slightly concave cylinder rather than a straight cylinder. Further, the annular flanges not necessarily have to be flat. For instance, instead of right annular flange described hereinabove, a rolling body of a semi-spherical shape, coaxial with the tubular-like member and fixedly attached thereto may be utilized. Further, the counterweight can be implemented, for instance, as a ring attached to outer surface of the right end section of the tubular-like member; the counterweight can be made of a non-metal material. The tubular-like member may have no openings on either of its ends so that the secondary roller could not be removed from the tubular-like member. Also, the primary roller in the embodiments described hereinabove can be implemented without the counterweight. In such implementation, the secondary roller must be heavy enough to cause the primary roller tilting to the left or to the right when the secondary roller is in the left end or in the right end of the primary roller, correspondingly.
A game that may be played on a substantially flat horizontal surface, for instance, on a floor, utilizing the rolling toy described hereinabove is contemplated. The game players, or one player, initially mark designated areas on the floor using a chalk or an adhesive tape: LAUNCH and TARGET, as shown in
While the disclosed technology has been taught with specific reference to the above embodiments, a person having ordinary skill in the art will recognize that changes can be made in form and detail without departing from the spirit and the scope of the disclosed technology. The described embodiments are to be considered in all respects only as illustrative and not restrictive. All changes that come within the meaning and range of equivalency of the claims are to be embraced within their scope. Combinations of any of the methods and apparatuses described hereinabove are also contemplated and within the scope of the invention.
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