The present application claims priority under 35 U.S.C. 119 to Japanese Patent Application No. 2020-120676 filed on Jul. 14, 2020. The entire content of Japanese Patent Application No. 2020-120676 is incorporated herein by reference.
The present invention relates to a top toy.
Items such as that noted in Patent Document 1, for example, have been known as top toys from the past. This top toy has a configuration in which a holding mechanism of a protruding moving part built into the toy body interior does a sliding operation vertically due to impact force, and when the holding mechanism is released by the sliding operation, the configuration is such that the protruding moving part is made to protrude by centrifugal force due to rotational force given to the toy body or the elastic effect of an elastic member.
However, with the top toy noted in the abovementioned Patent Document 1, this item did not allow the player to control the timing of transformation, and was lacking in strategic qualities.
The present invention was created considering these points, and its purpose is to provide a top toy that has excellent strategic qualities, with it possible for the player to customize the timing of transformation.
A top toy for rotating in a first direction on a floor around a central axis extending in an axial direction is provided. The top toy includes first and second shaft side components, and a trunk part. The first shaft side component extends in the axial direction. The trunk part is configured on the first shaft part component. The trunk part includes a trunk body, a moving body being rotatably configured with respect to the trunk body, and a locking mechanism. The moving member is movable between first and second positions in the axial direction. The locking mechanism is configured to lock releasably the moving member at the first position. The first shaft side component being rotatably configured with respect to the trunk part between first and second rotation positions with the axial direction as a center. The trunk part is rotatably configured with respect to the first shaft side component in a second direction being opposite to the first direction when an external force is applied to the trunk part. The first shaft side component includes a first projecting part. When the first projecting part is in contact with the locking mechanism, the locking mechanism is configured to release the moving member from the first position. The first and second shaft side components are interchangeable.
Following, a top toy of the present invention is explained based on an embodiment shown in the drawings.
The top toy 1 of the present embodiment is the top toy that can be used in a so-called battle game. This top toy 1 is used in a battle game in which the other party top toy 1 is disassembled by impact force by colliding with each other, etc., for example.
Broadly speaking, this top toy 1 comprises a shaft part 10, a flywheel 53, and a trunk part 20. In this specification, the items called shaft side components include the shaft part 10, and also include the parts that rotate integrally with the shaft part 10 (with the present embodiment, for example, the flywheel 53 that rotates integrally with the shaft part 10).
The shaft part 10 has a rotation shaft 11a for landing. A cylindrical body 11b is attached on top of the rotation shaft 11a. Claws 11c, 11c that jut radially outward are formed on the peripheral surface top edge of the cylindrical body 11b. The rotation shaft 11a and the cylindrical body 11b configure a shaft lower part 11, and jutting parts 11d, 11d are formed on this shaft lower part 11.
The shaft part 10 also has a cylinder body 12. A flange 12a is formed on the outer periphery bottom edge of this cylinder body 12, and square holes 12b, 12b are formed over the flange 12a from the peripheral wall of the cylinder body 12. Furthermore, protruding parts 12c, 12c are formed on the peripheral wall of the cylinder body 12.
The shaft part 10 also has a ring 13. Hook-shaped legs 13a, 13a are formed on the bottom edge outer periphery of this ring 13 (see
The shaft part 10 has a coil spring 14 wound around the cylindrical body 11b of the shaft lower part 11, and from above that, matches the claws 11c, 11c and the notch parts 13c, 13c and engages the ring 13 on the cylindrical body 11b, and furthermore, the legs 13a, 13a and the square holes 12b, 12b are matched to cover the cylinder body 12, and assembly is done by screws (not illustrated) passed through the jutting parts 11d, 11d being screwed into the protruding parts 12c, 12c.
With the shaft part 10 configured in this way, the ring 13 is energized upward by the coil spring 14, and the upward movement of the ring 13 is regulated by the legs 13a, 13a butting against the upper edge of the square holes 12b, 12b.
The flywheel 53 is used covering the shaft part 10 from above. The plan view center part of the flywheel 53 is elevated with respect to the peripheral part, and a hole 53b in which the cylinder body 12 of the shaft part 10 is inserted from below is formed on the ceiling wall of an elevation part 53a.
Bulging parts 53c, 53c that bulge facing upward of the shaft part 10 are formed on the ceiling wall of the elevation part 53a of the flywheel 53. Recesses 53d, 53d that open downward and inward of the flywheel 53 are formed below each bulging part 53c. The protruding parts 12c, 12c of the shaft part 10 are inserted from below in these recesses 53d, 53d. The top surface of the flange 12a of the shaft part 10 is abutted on the ceiling wall bottom surface of the elevation part 53a.
Also, projecting pieces 53e, 53e extending upward are formed on the top of the bulging parts 53c, 53c of the flywheel 53. These bulging parts 53c, 53c are inserted from below in arc-shaped holes 21d, 21d described later.
Furthermore, projections 53g, 53g that bulge upward as shown in
As shown in
The trunk body 21 is configured in a cylindrical form. As shown in
Of these, on the upper trunk part 21a, a bridge 21c is formed hanging across two parts facing sandwiching the shaft center.
In the upper trunk part 21a, arc-shaped holes 21d, 21d are formed on both sides of the bridge 21c. The bulging part 53c of the flywheel 53 is inserted from below in each arc-shaped hole 21d.
A hole 21e is also formed in the center of the bridge 21c. As shown in
Furthermore, boss holes 21h, 21h are formed at prescribed intervals in the circumferential direction on each fan-shaped end part of the bridge 21c. One each of a boss with a screw hole 23a of the upper ring 23 is fitted in each of the boss holes 21h. Also, on the bottom surface of each fan-shaped end part of the bridge 21c, a boss 21i is provided in the part between the boss holes 21h, 21h (see
As shown in
As shown in
Attached to the trunk body 21 configured in this way are a locking member 26, a pressing member 27, and a locking mechanism 28 (see
Of these, the locking member 26 is configured by a plate that is long in the horizontal direction. This locking member 26 is installed inside a hole 21n formed on each fan-shaped end part of the bridge 21c. A claw 26a is formed at the longitudinal center on the inner surface of each locking member 26. Both end parts of the claw 26a have elasticity. A claw 22a on each end in the longitudinal direction of the tip 22 is locked on each claw 26a. This results in the tip 22 being attached to the trunk body 21. On the outer surface of each locking member 26, a projecting piece 26b that extends in the vertical direction is formed in the longitudinal center, and during attachment of the locking member 26 to the trunk body 21, the projecting piece 26b is plugged into a slit 210 of the upper trunk part 21a.
The pressing member 27 presses the lower ring 25 described later downward, and is configured from a pressing unit 27a that protrudes from the trunk body 21 and abuts the top surface of the inward facing bulging part 25a of the lower ring 25, and a coil spring 27b that energizes the pressing unit 27a facing downward.
Each locking mechanism 28 comprises a locking member 28a that has a claw 28d, a coil spring 28b that energizes the locking member 28a facing the outside of the upper trunk part 21a, and a lock release member 28c that has a protruding part 28e that protrudes from the bottom surface of the lower trunk part 21b.
Also, under normal conditions, the claw 28d of each locking mechanism 28 protrudes from the outer periphery of the upper trunk part 21a by the energizing force of the coil spring 28b, is fitted in a recess 25b below the bulging part 25a of the lower ring 25 that has ascended, and holds the lower ring 25 in the ascending position (first position).
Also, the protruding part 28e of each lock release member 28c abuts the top surface of the plan view peripheral part 53f of the flywheel 53 that operates at the lower side.
Also, each lock release member 28c is moved upward when each protruding part 28e contacts the projection 53g of the flywheel 53, the locking member 28a is in sliding contact with each lock release member 28c, and that locking member 28a is operated facing inward of the upper trunk part 21a in resistance to the energizing force of the coil spring 28b, and each claw 28d is sunken from the outer periphery of the upper trunk part 21a.
As a result, the lower ring 25 for which rotation was restricted by the claws 28d, 28d of the locking members 28a, 28a is released from that restriction, and is made to descend by the energizing force of the coil spring 27b of the pressing member 27 (second position). The middle ring 24 may also be configured to descend by gravitational force.
The tip 22 covers the top surface of the bridge 21c of the trunk body 21.
Claw members 22d, 22d that extend downward are formed at both end parts in the longitudinal direction of the tip 22. The outward facing claw 22a is formed at the bottom edge of each claw member 22d. Each claw 28a is locked to the claw 26a of the inner surface of the locking member 26 attached to the upper trunk part 21a.
Also, other claw members 22b, 22b that extend downward are formed on the tip 22. Inward facing claw 22c is formed on the bottom edge of each claw member 22b. This claw member 22b is inserted in the hole 21e of the bridge 21c of the upper trunk part 21a, and in the inserted state, the claws 22c and the teeth 21g are adjacent in the circumferential direction.
The upper ring 23 covers and decorates the outer periphery top part of the trunk body 21. Many corrugated parts are formed on the top surface and outer periphery of this upper ring 23. Bosses with a screw hole 23a, 23a, and bosses 23b, 23b are formed on the bottom surface of the upper ring 23.
The middle ring is formed to be thin, and has corrugated parts formed on the outer periphery. This middle ring 24 is supported on the trunk body 21 to be able to rotate.
The lower ring 25 is formed to be thick, and has corrugated parts formed on the outer periphery. Also, on the upper edge part outer periphery of the lower ring 25, a recess 25d is formed in which a convex part 24a of the outer periphery of the middle ring 24 is fitted from above. As a result, when the lower ring 25 is in the ascending position, the recess 25d of the lower ring 25 is engaged with the convex part 24a of the outer periphery of the middle ring 24, and rotation of the middle ring 24 is obstructed.
Also, the bulging parts 25a and the recesses 25b are formed on the inner periphery of the lower ring 25. When the lower ring 25 has ascended, the pressing unit 27a of the pressing member 27 is abutted on the top surface of the bulging part 25a, and also, the claws 28d are engaged with the recesses 25b. Also, when the lower ring 25 is descended, the bottom surface of the bulging part 25a abuts a hinge 21p of the lower trunk part 21b, obstructing any further descending.
The shaft part 10 and the trunk part 20 of the top toy 1 are assembled as described hereafter.
First, the protruding part 12c of the shaft part 10 is made to match the recess 53d of the flywheel 53 from below, and the flywheel 53 covers the shaft part 10. Also, the shaft side components are matched to the trunk part 20. This state is a state in which the claws 11c, 11c of the shaft part 10 and the claws 22c, 22c of the trunk part 20 do not overlap in the vertical direction, specifically, a joining release state. After that, the shaft part 10 is further pressed on the trunk part 20 side. Having done that, the ring 13 is pressed by the claws 22c, 22c of the trunk part 20, flexing the coil spring 14, and the claws 11c, 11c of the shaft part 10 are pressed upward further above than the claws 22c, 22c of the trunk part 20. Also, the shaft side components are rotated in one direction (reverse direction to the rotation of the top) with respect to the trunk part 20. Having done that, the claws 11c, 11c of the shaft part 10 and the claws 22c, 22c of the trunk part 20 are in a state overlapping vertically (first rotation position). When the hand is released from the shaft side component in this state, the bottom surface of the claws 11c, 11c of the shaft part 10 and the top surface of the claws 22c, 22c of the trunk part 20 are abutted by the energizing force of the coil spring 14 within the shaft part 10. This state, specifically, the state in which the bottom surface of the claws 11c, 11c of the shaft part 10 and the claws 22c, 22c of the trunk part 20 are abutted, is the joined state. As a result, the shaft part 10 and the trunk part 20 are joined and the top toy 1 is assembled. In this assembled state of the top toy 1, the protrusions 13d, 13d of the shaft part 10 and the teeth 21g, 21g of the trunk part 20 are abutting.
Following, battle between top toys 1 is described.
The top toy 1 is rotationally energized by rotating a fork inserted from above in arc-shaped holes 21d, 21d, and is released into a prescribed field. Then, when there is a collision with the other party top toy, by impact force, rubbing, etc., due to the collision, a force in the direction opposite to the rotation direction of the shaft part 10 acts on the trunk part 20, and that causes the trunk part 20 to rotate relatively in the direction opposite to the rotation direction of the shaft part 10.
At this time, with the shaft part 10 and the trunk part 20, the protrusions 13d, 13d of the shaft part 10 and the teeth 21g, 21g of the trunk part 20 abut, and frictional resistance occurs due to the energizing force of the coil spring 14 within the shaft part 10, so for each acting of impact force on the trunk part 20, the shaft part 10 rotates relative to the trunk part 20 and changes the engagement position. Also, as shown in
Even after the middle ring 24 and the lower ring 25 are free to rotate, the relative rotation of the trunk part 20 and the shaft part 10 progress according to the angle at which the impact force acts, etc. Also, at the joining release position (second rotation position), specifically, when the projecting pieces 53e, 53e of the flywheel 53 that rotate integrally with the shaft part 10 reach the end of the arc-shaped holes 21d, 21d, the claws 22c, 22c of the trunk part 20 separate from the claws 11c, 11c of the shaft part 10, so the trunk part 20 separates from the shaft part 10 by the energizing force of the coil spring 14 within the shaft part 10 to be disassembled. The flywheel 53 also breaks away from the shaft part 10.
In this way, with the present embodiment, a gimmick is provided whereby the middle ring 24 and the lower ring 25 go from a state in which rotation is restricted to a state in which they are free to rotate. It is also possible to change the activation timing of the gimmick if the flywheel 53 is exchanged.
Therefore, it is possible to obtain the following effect.
Specifically, customization by the player, in other words, control to some degree of the timing of changes in top characteristics by exchanging of the flywheel 53 is possible, so it is possible to realize a top toy 1 with excellent strategic qualities.
Above, an embodiment of the present invention was explained, but the present invention is not limited to this embodiment, and it goes without saying that various modifications are possible within a range that does not stray from the gist.
For example, with the above embodiment, the gimmick was to have the middle ring 24 and the lower ring 25 go from a state in which rotation was restricted to a state of being free to rotate, but as shown in
As shown in
Also, when the flywheel 53 rotates relatively with respect to the trunk part 20 by a prescribed angle, the locking member 62 is pressed upward by a projection (not illustrated), the claw 62a of the locking member 62 separates from the recess 63 of the ring 60, and the ring 60 rotates to the second position by the energizing force of the coil spring 61.
It is also possible to have a portion of the outer periphery of the top toy 1 protrude in the radial direction outward by relative rotation of the flywheel 53 with respect to the trunk part 20.
It is also possible to have the projecting part 53g be able to move or be detachable with respect to the flywheel 53, and for the player to be able to change the position of the projecting part 53g with respect to the flywheel 53. Furthermore, in the case of the top toy in which the flywheel 53 is incorporated in the trunk part 20, it is also possible to provide the projection part 53g on the shaft part 10 itself. When providing the projecting part 53g, it is preferable that in the state with the trunk part 20 and the shaft side components joined, this not be visible from outside, as with the top toy 1 of the embodiment.
Also, as the top toy to which the present invention is applied, this is not limited to being a top toy for which it is possible for the trunk part 20 and the shaft side component to be disassembled by battling.
According to the top toy of the present invention, by customization by the player, specifically, exchanging of all or a portion of the shaft side components, it is possible to control the timing of changes in the top characteristics to some degree, and possible to realize a top toy with excellent strategic qualities.
Number | Date | Country | Kind |
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2020-120676 | Jul 2020 | JP | national |