JP6656683B1 - Top toy - Google Patents

Abstract

PROBLEM TO BE SOLVED: To change a body of a frame toy in a change mode rich in interest. A top toy (1) includes a body (40) and a shaft (10). The body 40 has a first movable part 61 configured to be movable stepwise within a predetermined movable range, and a movable range partially overlapping with the movable range of the first movable part 61. And a second movable part 62 whose movable range changes in accordance with the position of 61. [Selection diagram] Fig. 9

Description

  The present invention relates to a top toy.

2. Description of the Related Art Conventionally, there has been known a toy having a body and a shaft, in which a movable portion movable in a circumferential direction is attached to the body (for example, see Patent Document 1).
In this top toy, the movable section moves within its movement range in accordance with its own rotation or collision with the opponent's top toy, and a two-stage attack is made on the opponent's top toy by moving the movable section. be able to.

Patent No. 6250202

  However, in the above-mentioned conventional top toy, since the movable portion simply moves within the moving range, the state of the body is hardly changed, and there is a lack of interest in that point.

  The present invention has been made in view of such a problem, and an object of the present invention is to provide a toy toy whose torso changes in an interesting and varied manner.

The first means is a top toy having a body and a shaft,
Said torso,
A first movable part configured to be movable stepwise within a predetermined movable range;
A second movable component having a movable range that partially overlaps the movable range of the first movable component, wherein the movable range changes according to the position of the first movable component;
Have a,
The second movable component is urged in a rotation direction side of the top toy in a plane orthogonal to an axis of the top toy .

The second means is the first means,
The first movable component is configured to be irreversibly movable in a direction opposite to a rotation direction of the top toy along a circumferential direction of the body by a ratchet mechanism.

The third means is the second means,
The first movable component is configured to be irreversibly movable in a direction opposite to the rotation direction by the ratchet mechanism.

The fourth means is any one of the first means to the third means ,
The second movable component is urged toward the rotation direction by a coil spring.

The fifth means is any one of the first means to the fourth means,
Said torso,
A first state in which the first movable part is in contact with an end of the second movable part opposite to the rotation direction of the top toy, and movement of the second movable part is restricted;
A second state in which the first movable component moves in a direction opposite to the rotation direction from the first state and the second movable component is movable.
It is characterized by changing to at least two states.

The sixth means is the fifth means,
The body is configured such that the first movable component further moves from the second state in a direction opposite to the rotation direction and abuts on an end of the second movable component on the rotation direction side, and the second movable component is moved. It is characterized in that the state further changes to the third state in which the movement of the part is restricted.

The seventh means is any one of the first means to the sixth means,
The first movable component and the second movable component have the same number, and are arranged alternately along the circumferential direction of the body at the outer peripheral portion of the body.

Eighth means is any of the first to seventh means,
The body has a support member that supports the first movable component and the second movable component,
The support member has a high elasticity portion made of a material having higher elasticity than the first movable component and the second movable component on an outer peripheral portion,
The high elasticity portion is gradually exposed from the first movable component and the second movable component according to a change in the position of the first movable component and the second movable component.

According to the first means, the first movable component configured so that the body of the top toy can be moved stepwise within a predetermined movable range, and the movable portion that partially overlaps the movable range of the first movable component A second movable component having a range, wherein the movable range changes according to the position of the first movable component. That is, in this body, the first movable component moves stepwise, and at the same time, the movable range of the second movable component changes due to being restricted by the first movable component.
Therefore, the torso of the top toy can be changed in an interesting and varied manner.

(A) is a perspective view of one embodiment of the top toy according to the present invention, and (b) is a view for explaining how to play it. It is an exploded perspective view of a top toy. It is the disassembled perspective view which looked at the trunk | drum from the upper side. It is the disassembled perspective view which looked at the torso from the lower side. (A) It is the perspective view which looked at the chip from the upper side, and (b) is the perspective view which looked at the chip from the lower side. It is sectional drawing along the circumferential direction of the fuselage for demonstrating the moving structure (ratchet mechanism) of a 1st movable part. It is a top view of the transparent part periphery of the upper layer member in a fuselage. It is the perspective view which showed an example of the launcher which rotationally drives a top toy. It is a top view of the body for explaining movement of the 1st movable part and the 2nd movable part with respect to the upper layer member and the lower layer member. It is a top view of the body for explaining movement of the 1st movable part and the 2nd movable part with respect to the upper layer member and the lower layer member.

  Hereinafter, an embodiment of a top toy according to the present invention will be described with reference to the drawings.

<< 1. overall structure"
FIG. 1A is a perspective view of an embodiment of a top toy according to the present invention, and FIG. 1B is a diagram illustrating how to play the toy.
As shown in FIG. 1A, the top toy 1 of the present embodiment is a top toy that can be used in a so-called top battle game. This top toy 1 is composed of a shaft portion 10 constituting a lower structure, a variable performance ring 30 and a body 40 constituting an upper structure. It can be used for a battle game in which the game is decomposed to win as shown in FIG.

<< 2. Detail composition >>
2-1. Shaft 10 FIG. 2 is an exploded perspective view of the toy 1 in which the shaft 10 and the variable performance ring 30 are sectioned. In this specification, up, down, left, right, front and rear refer to the directions shown in FIG.
As shown in this figure, the shaft portion 10 includes a rotating shaft 11 at a lower end portion, a flange 12 at an upper and lower middle portion, and a cylindrical portion 13 at an upper portion. The rotating shaft 11, the flange 12, and the cylindrical portion 13 are formed of a synthetic resin. Of course, the material is not limited to a synthetic resin, and may be entirely or partially made of metal, rubber, or another material.
The lower portion of the flange 12 has a shape that is gradually narrowed from the flange 12 toward the rotating shaft 11, and is formed in a substantially inverted conical shape as a whole.
The flange 12 and the cylindrical portion 13 sandwich an axis Ax of the rotating shaft 11 (hereinafter, simply referred to as “axis Ax”) that coincides with the axis of the entire toy 1 along the up-down direction, and have one hole 15 in front and back. Are formed one by one. Further, the flange 12 and the cylindrical portion 13 are formed with protrusions 16 on the left and right sides of the flange 12 (only the left side is shown in FIG. 2). The protrusion 16 is located above and below the flange 12, and its outer surface is flush with the outer peripheral surface of the flange 12.
A cylindrical body 14 is provided inside the cylindrical portion 13. Although the upper end of the cylindrical body 14 is not particularly limited, it is set at a position slightly higher than the upper end of the cylindrical portion 13. Claws 17 projecting outward in the radial direction are formed one at a time at the upper end of the cylindrical body 14.

The shaft portion 10 includes a cylindrical movable member 18 provided inside the cylindrical portion 13 and surrounding the upper outer periphery of the columnar body 14. At the lower end of the movable member 18, projecting pieces 18a projecting outward in the radial direction are formed one by one in front and rear. Each protruding piece 18a is inserted into the hole 15. The movable member 18 is vertically movable. The movable member 18 is urged upward by a coil spring 19 wound around the cylindrical body 14, and the projecting piece 18 a is in contact with the upper edge of the hole 15 in a normal state.
On the upper surface 18b of the movable member 18, ridges 20 extending in the radial direction are formed one by one on the left and right (only the left one is shown in FIG. 2).

2-2. Performance Variable Ring 30 In the present embodiment, for example, a metal flywheel is used as the performance variable ring 30. The variable performance ring 30 has a substantially annular plate shape. An annular step portion 30a is formed on the bottom surface of the variable performance ring 30 so that the flange 12 of the shaft portion 10 can be accommodated from below. In addition, on the upper surface of the performance variable ring 30, one inverted U-shaped protrusion 31 is formed, which protrudes upward at each of the left and right sides (only the left side is shown in FIG. 2). A recess 32 is formed in a lower portion of each projection 31 so that the projection 16 of the shaft 10 can be accommodated from below. On the other hand, a tongue piece 33 projecting upward is formed on the upper surface of each projecting portion 31.
The variable performance ring 30 may be replaced with the flywheel or integrated with the flywheel, and has a protruding portion on the outer peripheral surface to facilitate attacking the opponent's top toy 1 or a concave portion on the outer peripheral surface. You may use what is hard to be attacked by the opponent's top toy 1.

2-3. FIG. 3 is an exploded perspective view of the torso 40 as viewed from above, and FIG. 4 is an exploded perspective view of the torso 40 as viewed from below. FIG. 5 is a perspective view of the tip 57 attached to the body 40. FIG. 6 is a cross-sectional view along the circumferential direction of the body 40 for explaining a moving structure (ratchet mechanism) of the first movable component 61 provided in the body 40, and FIG. FIG. 4 is a plan view of a periphery of a transparent portion 53 of the upper layer member 50.
As shown in FIGS. 3 and 4, the body 40 has a disk shape with the axis Ax as the central axis. The body 40 has a three-layer structure including an upper layer member 50, a middle layer member 60, and a lower layer member 70. More specifically, in the body 40, the upper layer member 50 and the lower layer member 70 are fixed to each other while vertically sandwiching the middle layer member 60 (the first movable component 61 and the second movable component 62) so as to be movable. It is configured.
In the following description, a direction along the axis Ax is referred to as an “axial direction”, a direction perpendicular to the axis Ax is referred to as a “radial direction”, and a circumferential direction around the axis Ax is referred to as a “circumferential direction”. Unless otherwise specified, “clockwise” or “counterclockwise” refers to the clockwise or counterclockwise direction of the circumferential direction when the top toy 1 is viewed in plan.

2-3a. Upper Layer Member 50 The upper layer member 50 is formed in a substantially disc shape with the axis Ax as a central axis. The upper layer member 50 is formed to be slightly narrower on the left and right in plan view, and has impeller-like irregularities rotating clockwise on the outer peripheral surface and the outer peripheral surface.
In the upper layer member 50, arc-shaped slits 51 into which the tongue pieces 33 of the performance variable ring 30 can be inserted from below are formed at two positions on the left and right, respectively. The circumferential length of each arc-shaped slit 51 is such that the tongue piece 33 can move sufficiently.

On the upper surface of the upper layer member 50, substantially arc-shaped surface parts 52 are attached one at each of two front and rear positions on the outer peripheral side. Two fitting protrusions 52a are provided upright on the lower surface of each surface part 52, and the fitting protrusions 52a are fitted into two through holes 50a provided in corresponding portions of the upper layer member 50. Each surface part 52 is attached to the upper layer member 50.
Further, the right and left outer peripheral portions of the upper layer member 50 are transparent portions 53 from which the lower intermediate member 60 and the lower layer member 70 can be visually recognized (see FIG. 7).

  On the lower surface of the upper layer member 50, two first bosses 54a and four second bosses 54b are provided upright. The first boss 54a is disposed at each of two locations on the left and right sides slightly outside the middle in the radial direction. Two second bosses 54b are arranged at two locations before and after the first boss 54a on the inner peripheral side. Each of the first boss 54a and the second boss 54b has a screw hole that opens downward. Further, the first boss 54a has a flat surface on a counterclockwise side as viewed from below for supporting a biasing spring 621 described later.

Further, on the lower surface of the upper layer member 50, a pair of guide projections 55a and guide grooves 55b for guiding a first movable component 61 of a middle layer member 60 described later are provided at two locations in front and rear. The guide protrusion 55a and the guide groove 55b of each set are arc-shaped protrusions or grooves along the circumferential direction, and are formed over a predetermined central angle range that is substantially the same and does not overlap.
Further, on the lower surface of the upper layer member 50, a set of two linear guide projections 56 for guiding a second movable component 62 of the later described intermediate layer member 60 are provided at two locations on the left and right. The linear guide projections 56 of each set are linear projections along a tangential direction centering on the axis Ax, and are provided on the same straight line on both front and rear sides across the first boss 54a.

A chip 57 as shown in FIG. 5 is mounted on the upper layer member 50.
The tip 57 is formed in a butterfly shape which is long in the front and back in plan view. The lower surface of the chip 57 is provided with one protruding portion 57a protruding downward, one on each side. The projecting portion 57a is inserted from above into the left and right sides of the hole 50b of the upper layer member 50 and the circular hole 71 of the lower layer member 70 (see FIGS. 3 and 4), and exposes the lower end surface below the body 40. On the lower end surface of the projecting portion 57a, a projecting portion extending in the radial direction is formed continuously in the circumferential direction, and an undulating portion 57b that meshes with the projecting ridge 20 of the shaft portion 10 is formed.
Further, on both front and rear ends of the chip 57, one locked piece 57c extending downward is formed.
Note that the chip 57 need not be provided.

2-3b. About Lower Member 70 As shown in FIGS. 3 and 4, the lower member 70 is formed in a substantially disk shape with the axis Ax as the central axis. The size of the lower layer member 70 in plan view is substantially the same as the size of the upper layer member 50. However, at least a part of each of the high elastic portions 70a provided at the four corners of the lower layer member 70 at the oblique front, rear, left and right protrudes (exposes) outward from the upper layer member 50 (see FIG. 10). The high elasticity portion 70a is formed of a lower layer member 70 main body excluding the high elasticity portion 70a, a rubber material having higher elasticity than a first movable component 61 and a second movable component 62 described later, and the like. Is formed by insert molding (integral molding) on the outer periphery.
At the center of the lower layer member 70, a circular hole 71 having the axis Ax as a central axis is formed. At the lower end of the inner peripheral surface of the circular hole 71, claws 71a projecting radially inward are provided at two obliquely front and rear portions.
An arcuate slit 72 is formed at each of two locations on the left and right sides of the lower layer member 70 radially outside the circular hole 71. Each arc-shaped slit 72 is formed at a circumferential position and a circumferential length corresponding to the arc-shaped slit 51 of the upper layer member 50.

  In the lower layer member 70, two first through holes 73a and four second through holes 73b are formed. The first through hole 73a and the second through hole 73b correspond to the first boss 54a and the second boss 54b of the upper layer member 50. Specifically, the first through-hole 73a and the second through-hole 73b are arranged at the same plane position as the corresponding boss, and a counterbore to which the lower end of the corresponding boss is fitted is provided on each upper surface side. A hole is formed. By screwing the screw 91 inserted through the first through hole 73a and the second through hole 73b from below into the screw holes of the corresponding first boss 54a and second boss 54b of the upper layer member 50, the upper layer member 50 is screwed. And the lower layer member 70 are fastened and fixed. However, the first boss 54a of the upper layer member 50 is screwed to the first through hole 73a in a state where the first boss 54a is inserted into the through hole 62a of the second movable component 62 described later.

On the upper surface of the lower layer member 70, a pair of guide projections 75a and guide grooves 75b for guiding the first movable component 61 of the later described intermediate layer member 60 are provided at two locations in front and rear. The guide protrusions 75a and the guide grooves 75b of each set correspond to the guide protrusions 55a and the guide grooves 55b of the upper layer member 50, and are similarly formed at substantially the same plane position as the guide protrusions 55a and the guide grooves 55b. I have. However, the center angle range of the guide projection 75a is slightly shorter than that of the guide projection 55a of the upper layer member 50.
Further, on the upper surface of the lower layer member 70, a pair of linear guide grooves 76 for guiding the second movable component 62 of the intermediate layer member 60, which will be described later, are provided at two locations on the left and right. The linear guide grooves 76 of each set are linear grooves parallel to the linear guide protrusions 56 of the upper layer member 50, and are provided on the same straight line with a predetermined gap therebetween.

The lower layer member 70 is provided with claw members 77 for positioning a first movable component 61 described later, one at each of two front and rear positions on the outer peripheral side.
Each claw member 77 is formed in a substantially flat plate shape, and is fitted and fixed to the upper surface of the lower layer member 70. Further, each claw member 77 has a hook portion 771 that meshes with a gear portion 611 of the first movable component 61 described later to form a ratchet mechanism. The hook portion 771 is formed in a beam shape extending counterclockwise along the circumferential direction, and is elastically displaced vertically with a clockwise end portion as a base end. Further, the hook portion 771 has a protrusion 771a upward at the tip. The projection 771a has a gentle slope on the base end side of the hook portion 771 and a steep slope on the tip end side, and is formed in a substantially triangular shape in a side view where these smoothly intersect at the upper end (see FIG. 6). .
In the present embodiment, the hook portion 771 is provided on the claw member 77 separate from the lower layer member 70 (main body) in order to impart desired elasticity and wear resistance to the hook portion 771. However, if other characteristics such as strength required for the lower layer member 70 main body and the above characteristics of the hook portion 771 can be compatible, the hook portion 771 may be provided integrally with the lower layer member 70 main body.

Further, the lower layer member 70 is provided with fixing members 78 for fixing the chip 57, one at each of two front and rear positions. In the body 40 of the present embodiment, the chip 57 is mounted at the center of the upper surface of the upper layer member 50, and the locked pieces 57 c (see FIG. 5) of the chip 57 To the vicinity of the upper surface of the lower layer member 70. The fixing member 78 is capable of switching the position in the radial direction with respect to the lower layer member 70 in a stepwise manner. By switching the position, the fixing member 78 is disengaged from the locked piece 57 c of the chip 57 and fixes or It can be released.
Note that the fixing member 78 may not be provided.

2-3c. Regarding the Middle Member 60 In the present embodiment, the middle member 60 includes two first movable components 61 and two second movable components 62. The two first movable parts 61 and the two second movable parts 62 are alternately arranged in the circumferential direction on the outer peripheral portion of the body 40, and are formed so as to be individually movable in a plane orthogonal to the axis Ax. It is supported by the member 50 and the lower layer member 70.

  The first movable component 61 is provided one at each of two locations before and after the outer peripheral portion of the body 40. Each first movable part 61 is formed in a substantially arc-shaped plate having a central angle of less than 90 degrees. The outer peripheral surface of each first movable component 61 has a radial position substantially coincident with the outer peripheral surface of the upper layer member 50 and the lower layer member 70. Depending on the position of the first movable component 61, the upper layer member 50 and the lower layer member 70 partially protrudes to the outer peripheral side.

An arc-shaped groove 61a and an arc-shaped projection 61b are formed on the upper surface of each first movable component 61. The arc-shaped groove 61a is an arc-shaped groove formed along the circumferential direction over substantially the half on the counterclockwise side. The arc-shaped projection 61b is an arc-shaped projection provided at the clockwise end. The arc-shaped groove 61a and the arc-shaped projection 61b correspond to the guide protrusion 55a and the guide groove 55b of the upper layer member 50. The arc-shaped groove 61a can slide on the guide protrusion 55a, and the arc-shaped projection 61b can slide on the guide groove 55b. Fit in state.
On the other hand, on the lower surface of each first movable component 61, an arc-shaped groove 61c and an arc-shaped projection 61d are formed. The arc-shaped groove 61c is an arc-shaped groove formed along the circumferential direction over a range slightly shorter than a substantially half portion on the counterclockwise side. The arc-shaped projection 61d is an arc-shaped projection provided at the clockwise end, and is provided at the same plane position as the arc-shaped projection 61b on the upper surface. The arc-shaped groove 61c and the arc-shaped projection 61d correspond to the guide protrusion 75a and the guide groove 75b of the lower layer member 70. Fit in state.
As described above, in each of the first movable parts 61, the arc-shaped groove 61 a and the arc-shaped projection 61 b are on the upper surface of the guide protrusion 55 a and the guide groove 55 b of the upper layer member 50, and the arc-shaped groove 61 c and the arc-shaped projection 61 d are on the lower surface. It is guided by the projection 75a and the guide groove 75b, respectively. Thereby, the first movable component 61 is movable in the circumferential direction with respect to the upper layer member 50 and the lower layer member 70.

On the lower surface of each first movable component 61, a crown gear-shaped gear portion 611 is formed along the circumferential direction. As shown in FIG. 6, each tooth 611 a of the gear portion 611 has a steeper counterclockwise (CCW side; left side in FIG. 6) surface and a clockwise side (CW side; right side in FIG. 6). The surface has a sawtooth shape formed more gradually. The surface on the clockwise side of each tooth 611a is formed slightly steeper than the surface on the same side of the projection 771a of the claw member 77.
The gear 611 meshes with a projection 771 a at the tip of the hook 771 of the claw member 77 to form a ratchet mechanism. By the ratchet mechanism, the position of the first movable component 61 is regulated by the elastic force of the hook portion 771 to a position where the projection 771a is engaged with the gear portion 611 (located between the teeth 611a). In other words, when the first movable component 61 moves counterclockwise (in the direction of the arrow in FIG. 6) with respect to the lower layer member 70 from the state where the projection 771a meshes with the gear portion 611, the hook portion 771 elastically deforms downward. Then, the first movable component 61 moves until it gets over the teeth 611a and returns to the original position again. Further, even if the first movable component 61 is to be turned clockwise, the hook portion 771 cannot be elastically deformed downward, so that the first movable component 61 cannot be moved in this direction.
With such a configuration, each first movable component 61 can be irreversibly moved counterclockwise over a predetermined central angle range stepwise from the initial state located at the most clockwise side. I have. In the present embodiment, the first movable component 61 is movable in a range of a central angle of about 25 degrees over a total of five steps.

  On the other hand, as shown in FIG. 3 and FIG. 4, the second movable parts 62 are provided one at each of two places on the left and right sides of the outer periphery of the body 40. Each second movable component 62 is formed in a long shape substantially along the front-back direction. The outer peripheral surface of each second movable component 62 protrudes slightly outward from the upper layer member 50 and the lower layer member 70 while the radial positions of the outer peripheral surfaces of the upper layer member 50 and the lower layer member 70 substantially coincide with each other.

At the center of each second movable component 62 in a plan view, a through hole 62a is formed vertically. The through hole 62a is formed to be long along the longitudinal direction of the second movable component 62. One end face of the through hole 62a on the counterclockwise side is formed in a semicircular shape in plan view corresponding to the first boss 54a of the upper layer member 50, and the other end face on the clockwise side is provided with an urging spring ( A support projection 62b for supporting the coil spring 621 is provided in a protruding manner.
On the upper surface of each second movable component 62, two linear grooves 62c are formed on both front and rear sides of the through hole 62a along the longitudinal direction of the second movable component 62. These two linear grooves 62c correspond to a set of linear guide protrusions 56 of the upper layer member 50, and the set of linear guide protrusions 56 is fitted in a slidable manner. I have.
On the other hand, on the lower surface of each second movable component 62, two linear projections 62d are formed at both ends in the longitudinal direction. These two linear projections 62d correspond to a pair of linear guide grooves 76 of the lower layer member 70, and the pair of linear guide grooves 76 are fitted in a slidable state. I have.
As described above, in each second movable component 62, the linear groove 62 c guides the linear guide protrusion 56 of the upper layer member 50 on the upper surface, and the linear protrusion 62 d guides the linear guide groove 76 of the lower layer member 70 on the lower surface. Is done. Thereby, the second movable component 62 is movable with respect to the upper layer member 50 and the lower layer member 70 in the longitudinal direction of the second movable component 62, that is, in the tangential direction about the axis Ax.
The first boss 54a of the upper layer member 50 is inserted into the through hole 62a of each second movable component 62. At this time, the biasing spring 621 is disposed in the through hole 62a between the other end surface on the clockwise side and the first boss 54a of the upper layer member 50. The biasing spring 621 is arranged to extend and contract along the longitudinal direction of the through hole 62a with one end supported by the support protrusion 62b. That is, the biasing spring 621 biases the second movable component 62 toward the upper layer member 50 clockwise along the longitudinal direction of the through hole 62a. Each of the second movable parts 62 is urged by the urging spring 621 so that the first boss 54a of the upper layer member 50 comes into contact with one end surface in the through-hole 62a (see FIG. 9A), and the second movable part 62 is turned counterclockwise. The urging spring 621 moves to the circumference side and moves to a state where the urging spring 621 is fully contracted (see FIG. 10). In this embodiment, it moves about 5 mm. The movable range of the second movable component 62 (the entire range of a single unit) partially overlaps each movable range of the two first movable components 61 adjacent on both sides in the circumferential direction.

  In the second movable component 62, the periphery of the through hole 62 a is located below the transparent portion 53 of the upper layer member 50. Therefore, as shown in FIG. 7, the user (player) can visually recognize the state and the like of the biasing spring 621 that expands and contracts in the through hole 62 a through the transparent portion 53 from above.

<< 3. Assembly method ''
Next, an overall assembling method of the toy 1 will be described. Assume that the assembly of the shaft 10 and the body 40 has been completed. A tip 57 is mounted on the body 40.
As shown in FIGS. 2 and 3, first, the shaft portion 10 and the variable performance ring 30 are assembled in a fitting state such that the protrusion 16 of the shaft portion 10 is aligned with the concave portion 32 of the variable performance ring 30 from below. . Next, the assembled body is approached to the body 40 from below. At this time, the tongue piece 33 of the performance variable ring 30 of the assembled body is aligned with the clockwise ends of the arc-shaped slits 51 and 72 of the body 40. In this state, the claws 17 of the shaft 10 and the claws 71a of the body 40 (the lower layer member 70) do not overlap in the vertical direction. This state is the uncoupled state. Thereafter, the shaft portion 10 of the assembled body is pressed toward the body 40. Then, first, the performance variable ring 30 is pressed against the lower surface of the body 40. Further, the coil spring 19 in the shaft 10 contracts, and the claw 17 of the shaft 10 is relatively pushed upward from the claw 71 a of the body 40. Then, the tongue piece 33 rotates the shaft 10 integrally with the performance variable ring 30 to the body 40 to the counterclockwise end opposite to the end. Then, the claws 17 of the shaft 10 and the claws 71a of the body 40 are vertically overlapped. When the hand is released from the shaft 10, the lower surface of the claw 17 of the shaft 10 and the upper surface of the claw 71 a of the body 40 are brought into contact with each other by the urging force of the coil spring 19 in the shaft 10. This state, that is, the state where the lower surface of the pawl 17 of the shaft portion 10 and the upper surface of the pawl 71a of the body 40 are in contact with each other is a combined state. As a result, the shaft portion 10, the variable performance ring 30, and the body 40 are connected, and the top toy 1 is assembled.

<< 4. how to play"
4-1. Basic Way of Playing Next, an example of a way of playing using the top toy 1 will be described.
FIG. 8 is a perspective view illustrating an example of a launcher that rotationally drives the top toy 1.
In one example of this playing method, the top toy 1 is rotated to battle the top toy 1 of the opponent.
In this case, the rotational force of the top toy 1 is charged by the launcher 80 as shown in FIG. The launcher 80 includes a disc (not shown) therein, and the disc is urged in one rotation direction by a spring (not shown), and a string (not shown) wound around the disc is pulled by a handle 81. Then, the disk is rotated, and the frame holder 83 is rotated. The rotation of the top holder 83 is transmitted to the top toy 1 by a fork 84 projecting downward, and rotates the top toy 1. In this case, the fork 84 is inserted into the arc-shaped slits 51, 72 of the body 40. When the handle 81 of the launcher 80 is pulled off, the rotation of the disc and thus the top holder 83 is stopped, while the top toy 1 is still rotated by the inertial force. Therefore, the top toy follows the inclined surface 84a of the fork 84. 1 comes off the top holder 83.
In FIG. 8, reference numeral 82 denotes a rod that can be moved into and out of the frame holder 83. When the top toy 1 is mounted on the top holder 83, the rod 82 is pushed by the upper surface of the top toy 1 and sinks into the top holder 83. The rod 82 is used, for example, to detect the attachment and detachment of the top toy 1.

In this embodiment, the top toy 1 fired in this manner rotates clockwise in a predetermined field. When the top toy 1 collides with the opponent's top toy 1, a force in a direction opposite to the rotation direction of the shaft 10 and the performance variable ring 30 acts on the body 40 due to an impact force or rubbing caused by the collision. Accordingly, the body 40 relatively rotates in a direction opposite to the rotation direction of the shaft portion 10 and the performance variable ring 30.
Then, each time the impact force due to the collision acts, the shaft portion 10 relatively rotates with respect to the body 40. At this time, the ridge 20 of the shaft 10 and the undulating portion 57b of the tip 57 mounted on the upper layer member 50 are engaged, and the urging force of the coil spring 19 acts on the ridge 20 of the shaft 10. ing. Therefore, each time the impact force acts, the ridge 20 and the undulating portion 57b act as a resistance element and change the meshing position, so that the body 40 and the shaft 10 rotate relatively. When the shaft 10 and the body 40 reach the uncoupling position, the claws 71a of the body 40 are disengaged from the claws 17 of the shaft 10, so that the body 40 is biased by the urging force of the coil spring 19 in the shaft 10. Move away from 10. As a result, the top toy 1 is disassembled as shown in FIG.

4-2. Next, a description will be given of how the torso 40 changes when the top toy 1 is used.
9 and 10 are plan views of the body 40 for explaining the movement of the middle layer member 60 (the first movable component 61 and the second movable component 62) with respect to the upper layer member 50 and the lower layer member 70. 9 and 10, in order to make the movement of the first movable component 61 and the second movable component 62 easy to understand, only the outer edge of the upper layer member 50 is shown by a two-dot chain line, and the first movable component 61 and the second movable component are shown. The outer edge of 62 is indicated by a thick line. Further, FIGS. 9B and 10 show a state in which the two first movable parts 61 have similarly moved, but the two first movable parts 61 can be individually moved.
As the top toy 1 of the present embodiment is used, the body 40 changes as the position and the movable range of the middle layer member 60 (the first movable component 61 and the second movable component 62) gradually change, and the top toy 1 of the other party is changed. The mode of collision with will also change.

Specifically, in the top toy 1 (body 40) in the initial state that has not been used much yet, as shown in FIG. 9A, the first movable component 61 is moved clockwise (in the rotational direction) of the movable range. Side), and the clockwise end face thereof is in contact with the counterclockwise end face of the second movable component 62. On the other hand, with the urging force of the urging spring 621, the second movable component 62 causes the urging spring 621 to extend completely in the through hole 62a, and causes the first boss 54a of the upper layer member 50 to rotate counterclockwise in the through hole 62a. , And is located on the clockwise side (rotational direction side) of the movable range. In this state, the second movable component 62 cannot move because the end surface on the counterclockwise side is in contact with the first movable component 61.
In this initial state (before the change), most of the high elasticity portion 70a of the lower layer member 70 is covered by the first movable component 61 or the second movable component 62, and the collision with the opponent's top toy 1 is exclusively caused by the first A simple collision mode by the first movable component 61 or the second movable component 62 is obtained.

When the first movable component 61 collides with the counterpart toy 1 in the initial state (or repeats this collision), the first movable component 61 is configured by the hook portion 771 of the claw member 77 and the gear portion 611. As shown in FIG. 9B, the ratchet mechanism moves the upper layer member 50 and the lower layer member 70 stepwise and irreversibly in a counterclockwise direction (a direction opposite to the rotation direction). Thereby, the clockwise end face of the first movable component 61 is separated from the counterclockwise end face of the second movable component 62. Therefore, the second movable component 62 is kept until the end face on the counterclockwise side comes into contact with the first movable component 61 (when the first movable component 61 is no longer located on the movement straight line of the second movable component 62). Within the range (until the urging spring 621 in the through-hole 62a is completely contracted), it is possible to move in the longitudinal direction against the urging force of the urging spring 621.
In the middle of the change, the high elasticity portion 70a of the lower layer member 70 is exposed from the clockwise side of the first movable component 61 as the first movable component 61 moves. Therefore, by colliding with the opposing top toy 1 at the two exposed high elastic portions 70a, a stronger attack than in the initial state can be delivered. Furthermore, since the second movable component 62 urged clockwise (that is, the same direction as the rotation direction) by the urging spring 621 becomes movable, when the second movable component 62 collides with the opposing top toy 1. In addition, the impact at the time of collision can be reduced by the biasing spring 621. Alternatively, when the urging force of the urging spring 621 is strong, the opposing toy 1 can be bounced back by this urging force.

When the first movable component 61 repeatedly collides with the counterpart toy 1 and further irreversibly moves counterclockwise, the counterclockwise end face of the first movable component 61 becomes second movable component 62. Abuts the end face on the clockwise side of. Then, the second movable component 62 is pushed by the first movable component 61 against the urging force of the urging spring 621 and moves counterclockwise, and its movable range gradually narrows. Then, as shown in FIG. 10, the biasing spring 621 is finally contracted and cut in the through hole 62a, so that the second movable component 62 cannot move further counterclockwise. In this manner, both the first movable component 61 and the second movable component 62 are located at the most counterclockwise side of each movable range (actual movable range in consideration of interference with an adjacent movable component) and are no more than It does not move and becomes a completely changed state.
In the state after the change, the height of the lower layer member 70 different from that previously exposed in the state in the middle of the change from the clockwise side of the second movable part 62 with the movement of each second movable part 62. The elastic part 70a is exposed. Therefore, by colliding with the opposing top toy 1 at the four exposed high elastic portions 70a, it is possible to launch an even stronger attack than the above-described state in the middle of the change.

<< Effect of this embodiment >>
As described above, according to the top toy 1 of the present embodiment, the first movable component 61 configured so that the body 40 can move stepwise within the predetermined movable range, and the movable configuration of the first movable component 61 A second movable component 62 having a movable range that partially overlaps with the range, wherein the movable range changes according to the position of the first movable component 61. That is, in the body 40, the first movable component 61 moves stepwise, and the movable range of the second movable component 62 is changed by being restricted by the first movable component 61.
Therefore, the torso 40 can be changed in an interesting manner.

Further, according to the present embodiment, the lower layer member 70 supporting the first movable component 61 and the second movable component 62 is made of a high elastic material made of a material having higher elasticity than the first movable component 61 and the second movable component 62. An elastic portion 70a is provided on the outer peripheral portion, and the high elasticity portion 70a changes the position of the first movable component 61 and the second movable component 62 to change the positions of the first movable component 61 and the second movable component. Exposure gradually from 62.
Accordingly, the body 40 can be changed such that a strong attack by the high elasticity portion 70a can be carried out by the high elasticity portion 70a with respect to the opposing frame toy 1 with the change in the position of the first movable component 61 and the second movable component 62.

<< Modification of the present invention >>
Although the embodiments of the present invention have been described above, the present invention is not limited to the embodiments, and it goes without saying that various modifications can be made without departing from the gist of the present invention.
For example, in the above embodiment, the first movable component 61 is configured to move stepwise in the circumferential direction by the ratchet mechanism, but the first movable component 61 moves stepwise within a predetermined movable range. The moving direction, the mechanism, the structure, and the like are not particularly limited as long as they can be configured.
Further, in the above embodiment, the first movable component 61 is configured to be irreversibly moved by the ratchet mechanism, but this movement may not be irreversible. For example, it may be configured such that the user can manually return the first movable component 61 that has moved during the game. Further, the first movable component 61 may be configured to be movable in one direction, but difficult to move in the opposite direction. Specifically, a contact portion may be provided on each of the first movable component 61 and the upper layer member 50 or the lower layer member 70 so as to relatively hinder the movement of the first movable component 61 in the opposite direction. . This structure may be used together with the ratchet mechanism.

  In the above embodiment, the second movable component 62 is configured to be movable in a tangential direction about the axis Ax, and is urged clockwise (rotational direction side) of the second movable component 62. And However, the second movable component 62 has a movable range that partially overlaps with the movable range of the first movable component 61, and the movable range changes depending on whether or not the first movable component 61 restricts the movable range. Should be fine. Therefore, the moving direction of the second movable component 62 and the urging direction thereof are not limited to those in the above embodiment. Furthermore, the second movable component 62 may not be biased.

  In the above embodiment, the state of the body 40 changes (evolves) in a plurality of stages due to the movement of the first movable component 61 by the ratchet mechanism. However, the body 40 has a first state in which the first movable part 61 is in contact with an end of the second movable part 62 on the opposite side to the rotation direction, and the movement of the second movable part 62 is restricted. It is sufficient that the first movable part 61 can be changed from the state described above to at least two states of the second state in which the first movable part 61 moves in the direction opposite to the rotation direction and the second movable part 62 can move. However, in the body 40, the first movable component 61 further moves in the direction opposite to the rotation direction from the second state, abuts on the end of the second movable component 62 on the rotation direction side, and the second movable component 62 More preferably, the state can be further changed to the third state in which the movement is restricted.

  In the above embodiment, two first movable parts 61 and two second movable parts 62 are provided. However, if the first movable part 61 and the second movable part 62 are the same in number, The quantity is not particularly limited.

  In the above embodiment, the rotation direction of the top toy 1 is clockwise, but this rotation direction may be counterclockwise. However, in this case, it is necessary to invert the shape and structure depending on the rotation direction (for example, the urging direction of the urging spring 621 and the moving direction of the first movable component 61 by the ratchet mechanism) in the circumferential direction. Of course.

1 frame toy 10 Shaft portion 40 Body 50 Upper layer member 53 Transparent portion 54a First boss 60 Middle layer member 61 First movable component 62 Second movable component 62a Through hole 70 Lower layer member 70a High elasticity portion 73a First through hole 77 Claw member 611 Gear 611a Tooth 621 Urging spring 771 Hook 771a Projection Ax Axis

Claims (8)

A top toy having a body and a shaft,
Said torso,
A first movable part configured to be movable stepwise within a predetermined movable range;
A second movable component having a movable range that partially overlaps the movable range of the first movable component, wherein the movable range changes according to the position of the first movable component;
Have a,
The top toy, wherein the second movable component is urged toward the rotation direction of the top toy in a plane perpendicular to the axis of the top toy.   The top toy according to claim 1, wherein the first movable component is configured to be movable in a direction opposite to a rotation direction of the top toy along a circumferential direction of the body by a ratchet mechanism. .   The top toy according to claim 2, wherein the first movable component is configured to be irreversibly movable in a direction opposite to the rotation direction by the ratchet mechanism. The top toy according to any one of claims 1 to 3, wherein the second movable component is urged toward the rotation direction by a coil spring. Said torso,
A first state in which the first movable part is in contact with an end of the second movable part opposite to the rotation direction of the top toy, and movement of the second movable part is restricted;
A second state in which the first movable component moves in a direction opposite to the rotation direction from the first state and the second movable component is movable.
The top toy according to any one of claims 1 to 4 , wherein the top is changed into at least two states. The body is configured such that the first movable component further moves from the second state in a direction opposite to the rotation direction and abuts on an end of the second movable component on the rotation direction side, and the second movable component is moved. The top toy according to claim 5 , further changing to a third state in which the movement of the part is restricted. The first movable part and the second movable part, those the same number of mutually, of claims 1 to 6, characterized in that it is arranged alternately along the circumferential direction of the body at the outer periphery of the body The top toy according to any one of the above. The body has a support member that supports the first movable component and the second movable component,
The support member has a high elasticity portion made of a material having higher elasticity than the first movable component and the second movable component on an outer peripheral portion,
The said high elasticity part is gradually exposed from the said 1st movable component and the said 2nd movable component according to the change of the position of the said 1st movable component and the said 2nd movable component, The Claims 1-7 characterized by the above-mentioned. A toy according to any one of the preceding claims.

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