JP6491780B1 - Top toy - Google Patents

Abstract

[PROBLEMS] To provide a top toy which can be easily recombined and can enjoy morphological change in the horizontal direction. SOLUTION: A body is supported by a launcher, and it is configured to be rotationally urged and launched while supported by the launcher, and it is possible to support at the time of the rotation energizing by the launcher and determine the rotation energizing direction by the launcher. In a toy top toy having a force direction determination unit, the body is coupled to and releasable from each other, and when it is joined, the two longitudinally split and half body pieces 42A and 42B that constitute the body form the body body 42 And a rotation biasing direction determination part 50 configured to be detachable and formed with a rotation biasing direction determination part, and each of the two body pieces 42A, 42B is configured to be interchangeable with an alternative body piece . [Selected figure] Figure 5

Description

  The present invention relates to a top toy.

As a battle game using a top toy, a top toy is made to collide with each other, and the impact force is used to stop the rotation of the top toy of the other party, to flip the top toy of the other party, to disassemble the top toy of the other party is there.
In such a battle game piece toy, a blade-like projecting portion is formed on a portion that collides with the other piece toy, that is, the circumferential surface of the trunk, and the projecting portion is made to collide.

  As such a piece toy, there is known one configured by a plurality of layered body pieces (body pieces) stacked in the longitudinal direction (vertical direction) (for example, see Patent Document 1). According to this kind of toy top toy, it is possible to change the characteristics of the toy top toy by preparing an alternative trunk piece having a different outer shape, weight or material and replacing the trunk piece on a trunk piece basis.

Utility model registration 3079269 gazette

By the way, a top toy hits the top toy etc. of the other party in the uneven part of the outermost circumference. Therefore, when viewed from the outer shape of the torso, the characteristics of the top toy largely depend on the shape of the uneven portion at the outermost periphery of the torso.
Therefore, if it is intended to change the characteristics of the top toy by changing the shape of the uneven portion at the outermost periphery of the body, in the case of the top toy, the outer shape of the shell piece constituting the uneven portion at the outermost periphery of the body is changed It is necessary to
However, in the case of the top toy, since the layered shell pieces are stacked, each shell piece must be thinner and more brittle than the one-piece body part. Therefore, in the case of the top toy, it is necessary to stack a plurality of shell pieces having substantially the same outer shape, which constitutes the uneven portion of the outermost periphery of the trunk, in order to have a structure sufficiently resisting collision with the partner top toy etc. However, it is troublesome to prepare a plurality of shell pieces having substantially the same outer shape.
Further, the characteristics of the cotter toy also depend on the weight and material of the body. This is because if the weight or the material changes, the impact force, the rotation characteristics, or the like given to the other top toy or received by the top toy changes.
However, in the case of the cotter toy, each one of the torso pieces themselves is made of a uniform material and generally has a balanced shape in the circumferential direction, so, for example, torso pieces having different weights The center of gravity changes only in the vertical direction even if Moreover, even if it changes to the trunk piece from which a material differs, a characteristic becomes uniform in the circumferential direction. That is, regardless of where in the circumferential direction the top toy hits, for example, the cushioning effect becomes uniform.
In terms of design, the upper surface of the torso portion is a portion that is particularly easy for the viewer to see, but in the case of the top toy, design changes can not be enjoyed unless the top piece is replaced.

  This invention is made in view of this point, and it is an object of the present invention to provide a top toy which can be easily rearranged and which can enjoy a change in form in the horizontal direction.

The first means is
The body is supported by the launcher, and is configured to be rotationally biased and launched, and the launcher enables the support at the time of the rotation bias by the launcher and determines the direction of the rotation bias by the launcher. In the top toy having the determination section,
The barrels are configured so as to be mutually coupled and releasably connected to each other and longitudinally split and split into two barrel pieces that constitute the barrel main body when coupled;
A rotation biasing direction determination component that is configured to be detachable from the barrel body and in which the rotation biasing direction determination portion is formed;
Each of the two shell pieces is characterized in that it is configured to be interchangeable with an alternative shell piece.

The second means is characterized in that, in the first means, the rotational biasing direction determining component mediates the connection between the shaft portion and the barrel body.

  As a third means, in the second means, the cylinder body is formed in an annular shape so as to have a hole in the center, and the rotational biasing direction determining part is partially in the hole in the center of the cylinder body when mounted. Is inserted.

  A fourth means is according to the third means, wherein the rotational biasing direction determining part has a vertically extending axial center insertable into the central hole, and an upper opening of the cylindrical body. And a cover member for closing the cover.

  As a fifth means, in the fourth means, a clamping piece is attached to the outer periphery of the cylindrical body, and a clamping piece is attached to the inner periphery of the central hole of the barrel main body The determining part is mounted on the cylinder main body by holding the piece to be held between the holding piece and the cover member by inserting and rotating the cylindrical body into the hole of the cylinder main body. It features.

  Sixth means is any one of the first means to the fifth means, wherein a fork of the launcher is inserted into each of the two trunk pieces when the top toy is rotationally biased. Slits are formed respectively, and two of the rotation biasing direction determining units are provided to correspond to the respective arc-shaped slits, and each of the rotation biasing direction determining units includes the rotation biasing direction determining part In a state of being mounted on the body, the projection may be projected to a predetermined position in the corresponding arc-shaped slit to narrow the width of the arc-shaped slit.

According to the first means, since the torso piece can be replaced with an alternative torso piece, it is possible to easily form the appearance of the favorite toma toy or change the characteristics of the toma toy . Specifically, the body piece can be changed to a favorite toy of the top by rearranging the body piece into body pieces having different shapes such as color, pattern, shape or structure, or a combination thereof. The structure also includes material and weight.
In addition, since the rotation biasing direction determination unit is formed separately from the body piece, the body piece can be replaced relatively freely. That is, although it is usual to provide a plurality of rotation biasing direction determination parts in the circumferential direction on the balance of the top toy, simply by dividing the trunk into two, the rotation biasing direction determination parts are included in both trunk pieces You Therefore, only the shell pieces in the same rotation biasing direction can be combined, but according to the i-th means, it is possible to combine not only the one in the same rotation direction but also the shell pieces in different rotation biasing directions.

  According to the second means, since the rotational biasing direction determining part is provided between the shaft and the barrel body, another gimmick may be incorporated between the rotational biasing direction determining part and the shaft. Can.

  According to the third means, since the rotation biasing direction determining part is mounted by inserting a part thereof into the center hole of the annular cylinder body, the mounting structure becomes simple.

  According to the fourth means, it is possible to mount the rotation biasing direction determination component on the body only by inserting the cylinder into the hole of the body and rotating it.

  According to the fifth means, only by inserting and rotating the cylindrical body into the hole of the trunk body, the rotation biasing direction determination component can be reliably mounted on the trunk body.

  According to the sixth means, it is possible to easily determine the rotation biasing direction of the top toy simply by causing the rotation biasing direction determination portion to protrude to the arc shaped slit.

It is a perspective view showing a top toy and a launcher (top launcher). It is an exploded perspective view of a top toy. It is a cross-sectional perspective view of the axial part of a top toy and the half part of a flywheel. It is a perspective view of the state which looked at the trunk part of the top toy from the lower part. It is a disassembled perspective view of the trunk | drum of a top toy. It is a bottom view of the trunk body of a top toy. It is the disassembled perspective view of the state which looked at the rotation energizing direction determination components of the top toy from the downward direction. It is a disassembled perspective view of the other trunk | drum of a top toy. It is a bottom view of the other trunk main part of the top toy. It is the disassembled perspective view of the state which looked at the other rotation biasing direction determination components of the top toy from the downward direction. It is a bottom view of the further another trunk body of a top toy. It is sectional drawing which showed the connection structure of a trunk | drum and an axial part. It is the bottom view which showed the connection relation of a cover member and the trunk | drum main body of FIG. It is the top view which showed another coupling structure of trunk pieces.

  Hereinafter, a top toy according to the present invention will be described based on an embodiment shown in the drawings.

(overall structure)
FIG. 1 shows a top toy 1 and a launcher (top launching toy) 60 of the present embodiment.
The top toy 1 is a top toy that can be used for a so-called battle game. The top toy 1 is rotationally biased by the launcher 60. Then, the top toy 1 is used, for example, in a battle game played by disassembling the other top toy 1 with an impact force due to a collision of each other.
As shown in FIG. 2, the piece toy 1 is roughly divided into a shaft 10, a flywheel 30 and a body 40.

(Detailed composition)
1. Shaft 10
FIG. 3 is a perspective view showing the shaft 10 and a half of the flywheel 30. As shown in FIG. This half is in plane symmetry with the other half. In the description of the shaft portion 10 and the flywheel 30, the directions shown in FIG.
Among them, the shaft portion 10 is provided with a rotary shaft 11 which is a grounding portion at the lower end portion, a collar 12 at the middle portion in the vertical direction, and a cylindrical body 13 at the upper end portion.
The crucible 12 and the cylindrical body 13 are integrally formed. A pillar 14 is provided at the center of the cylindrical body 13. On the outer periphery of the upper end portion of the column body 14, there are formed claws 17 projecting radially outward in the front and rear direction respectively. The column body 14 is fixed to the lower shaft portion 10a. The outer peripheral surface of the shaft lower portion 10a is gradually reduced in diameter from the crucible 12 side toward the tip side of the rotary shaft 11, and is formed in a substantially inverted conical shape as a whole. The lower shaft portion 10a is fixed to the crucible 12 by a screw or the like (not shown).
In the crucible 12 and the cylindrical body 13, one hole 13 a is formed in each of the front and back, respectively, across the crucible 12 and the cylindrical body 13. Further, on the outer peripheral surface of the cylindrical body 13, one protrusion 16 is formed on each of the left and right. The outer surface of each protrusion 16 is flush with the outer circumferential surface of the crucible 12.

  Further, the shaft portion 10 is provided with a cylindrical pressing member 18. The pressing member 18 has an annular portion 18 b shaped to fit on the outside of the upper end portion of the column 14, and the inside is hollow and opens downward. The pressing member 18 is disposed inside the cylindrical body 13 so as to surround the column body 14. On the outer periphery of the lower end portion of the pressing member 18, one leg portion 18a protruding radially outward in each of the front and rear is formed.

The pressing member 18 is assembled such that each leg 18a is exposed from the corresponding hole 13a. The holes 13a allow vertical movement of the legs 18a, but restrict upward movement at the upper edge of the holes 13a. Further, the pressing member 18 is urged upward by the spring 19, and in the normal state, the upper end surface of the pressing member 18 is at substantially the same height position as the upper end of the cylindrical body 13.
Note that, on the upper surface of the pressing member 18, one convex stripe (projection) 20 extending in the radial direction is formed on each of the left and right.

2. Flywheel 30
The flywheel 30 is formed in an annular shape. An annular step portion 30 a capable of accommodating the flange 12 of the shaft portion 10 from below is formed on the inner peripheral side of the bottom surface of the flywheel 30. On the upper surface of the flywheel 30, there are formed one projecting portion 31 projecting upward respectively to the left and right. The lower portion of each protrusion 31 is formed with a recess 32 capable of accommodating the protrusion 16 of the shaft 10 from below. Further, on the upper surface of the flywheel 30, tongues 33 extending upward are formed immediately outside the protrusions 31. As shown in FIG. The tongues 33 project above the projection 31.

3. Body 40 for clockwise rotation
4 is a perspective view of the trunk 40 as seen from below, FIG. 5 is an exploded perspective view of the trunk 40, and FIG. 6 is a bottom view of the trunk body 42. As shown in FIG. In the description of the torso portion 40, the directions shown in FIG. 4 are referred to unless otherwise specified.

  The body 40 includes a rotation biasing direction determination component 50 located at the center, and an annular trunk body 42 surrounding the rotation biasing direction determination component 50 and forming an outer peripheral portion of the top toy 1. The trunk body 42 is composed of semi-annular trunk pieces 42A and 42B. Then, the rotation biasing direction determination component 50 mediates the connection between the barrel body 42 and the shaft portion 10.

The trunk body 42 is configured to be split into a trunk piece 42A and a trunk piece 42B in a longitudinally split state in the left-right direction. The body pieces 42A and 42B have a substantially point-symmetrical shape. Then, when the body pieces 42A and 42B are butted against each other and assembled, a generally annular body body 42 is formed, and a circular hole 43 is formed at the center.
Around the trunk body 42 formed in this manner, a blade-like projecting portion 44 that collides with the other top toy is formed.

As shown in FIG. 6, in the body pieces 42A and 42B, one arcuate slit 45 into which each tongue 33 of the flywheel 30 can be inserted from below is formed. The width of each arcuate slit 45 in this case is the same in the circumferential direction, as shown in the figure. The two arcuate slits 45 are disposed near the inner periphery of the barrel body 42.
Further, at the front and back of the inner periphery of the trunk body 42, one nipped piece 48 projecting inward is formed. The two clamped pieces 48 have different circumferential dimensions. That is, each supported piece 48 is configured by combining two of the three pieces 48a, 48b, and 48c of large, medium, and small dimensions.
Specifically, a large-sized piece 48a is formed on the front end side of the body piece 42A, and a small-sized piece 48c is formed on the rear end side of the body piece 42A. On the other hand, a small-sized piece 48c is formed on the front end side of the body piece 42B, and a medium-sized piece 48b is formed on the rear end side of the body piece 42B. As a result, the gap between the piece 48a and the piece 48c in the body piece 42A is smaller than the gap between the piece 48c and the piece 48b in the body piece 42B. The technical significance will be described later.
Then, when the body piece 42A and the body piece 42B are joined, a supported piece 48 in which the piece 48a and the piece 48c are combined is formed on the front end side of the body body 42, and the rear end side of the body body 42 is formed. A sandwiching piece 48 is formed by combining the piece 48c and the piece 48b.

4. As shown in FIG. 5, convex stripes 46 having a T-shaped cross section extending substantially in the radial direction are formed at each of the front and rear butt portions of the body piece 42A. On the other hand, a concave groove 47 having a T-shaped cross section extending substantially in the radial direction is formed in each of the front and rear butt portions of the body piece 42B.
Then, the trunk body 42 is configured by bringing the trunk piece 42A closer to the trunk piece 42B from one direction in the radial direction and inserting the convex strips 46, 46 of the trunk piece 42A into the concave grooves 47, 47 of the trunk piece 42B. .

5. Rotation energizing direction determination part 50
FIG. 7 is an exploded perspective view showing the rotation biasing direction determination part 50. As shown in FIG. The rotation biasing direction determination component 50 is a component dedicated to clockwise rotation, and includes a cylindrical body 51 and a cover member 52. The cylindrical body 51 in this case is exclusively for clockwise rotation, and the arrangement and shape of the members are different from the cylindrical body 51 of the rotation biasing direction determination component 500 for counterclockwise rotation only, which will be described later.
At the lower end of the cylindrical body 51, two claws 51a protruding inward are formed in the circumferential direction with a gap 51b therebetween. The two claws 51 a are formed at positions facing each other across the axis of the cylindrical body 51. Then, on the lower surface of the rear end portion of the cotter toy 1 in the rotation direction of the claws 51a, there is formed an undulating portion 51c in which a plurality of convex stripes extending in the radial direction are arranged at predetermined intervals in the circumferential direction. Further, at the upper end of the outer wall of the cylindrical body 51, two protruding pieces 51d that project outward are formed with a gap therebetween. The two projecting pieces 51 d are formed at positions facing each other across the axis of the cylindrical body 51. Further, on the outer wall of the cylindrical body 51, two sandwiching pieces 51e protruding outward are formed at a position lower than the projecting piece 51d with a gap therebetween. The two holding pieces 51 e are formed at positions facing each other across the axis of the cylindrical body 51.
The holding piece 51e is formed at a position different from the protruding piece 51d in the circumferential direction. Moreover, the protrusion 51f is formed in the outer wall of the cylindrical body 51 below the rotation direction front-end part of the piece toy 1 in each clamping piece 51e. The two protrusions 51 f are used when the cylindrical body 51 is rotated relative to the cover member 52 by a rotating jig (not shown).

  The outer peripheral edge of the cover member 52 forms a wall that descends downward, and two rotation biasing direction determining portions 52 a that project into the arc-shaped slit 45 are formed on the wall. The two rotation biasing direction determination units 52a are formed at positions facing each other across the axis line of the cover member 52. When the cover member 52 is fitted to the trunk body 42, the two rotation biasing direction determination portions 52a project to the front end portion of the split slit 45 in the rotational direction of the piece toy 1 and narrow the width of the split slit 45 . Thereby, the rotation biasing direction of the top toy 1 is determined. This point will be described later. Further, a cylindrical portion 52 b is provided at the center of the lower surface of the cover member 52. The cylindrical portion 52 b is sized to fit inside the cylindrical body 51. Furthermore, on the lower surface of the cover member 52, two arc-shaped walls 52c are formed on the outer side of the cylindrical portion 52b concentrically with the cylindrical portion 52b with a space in the circumferential direction. The two arc-shaped walls 52c are equal in circumferential dimension, and are shaped to fit on the outside of the cylindrical body 51. A groove 52d into which the protrusion 51d is inserted is formed inside the arcuate wall 52c. Further, an insertion port 52e for inserting the protrusion 51d into the groove 52d is formed at a central portion of the groove wall of the arcuate wall 52c.

6. Barrel 400 for counterclockwise rotation
FIG. 8 is an exploded perspective view showing the body 400, and FIG. 9 is a bottom view of the body 42. As shown in FIG. In the description of the trunk 400, the directions shown in FIG. Further, the structure of the body 400 is the same as the structure and function of the body 40 except that the circumferential direction position and shape of the predetermined member are changed in accordance with the rotational direction. In the description, the same reference numerals are used for parts corresponding to the components of the body 40, and the description will be omitted as appropriate.

  The body 400 includes a rotation biasing direction determination component 500 and a body 42. The trunk body 42 is composed of semi-annular trunk pieces 42C and 42D. Then, the rotational biasing direction determination component 500 mediates the connection between the barrel body 42 and the shaft portion 10.

The trunk body 42 is configured to be divided into two into a trunk piece 42C and a trunk piece 42D. The body pieces 42C and 42D have a substantially point-symmetrical shape. Further, in the coupling structure of the body piece 42C and the body piece 42D, the body piece 42C corresponds to the body piece 42A, and the body piece 42D corresponds to the body piece 42B.
As shown in FIG. 9, a piece 48b is formed on the front end side of the body piece 42C, and a piece 48c is formed on the rear end side of the body piece 42C. On the other hand, a piece 48a is formed on the front end side of the body piece 42D, and a piece 48b is formed on the rear end side of the body piece 42D. Therefore, the gap between the piece 48b and the piece 48c in the body piece 42C is larger than the gap between the piece 48a and the piece 48b in the body piece 42D. The technical significance will be described later.

7. Rotation energizing direction determination part 500
FIG. 10 is an exploded perspective view showing the rotation biasing direction determination part 500. As shown in FIG. The rotation biasing direction determination component 500 is a component dedicated to counterclockwise rotation, and includes a cylindrical body 51 and a cover member 52.
The cylindrical body 51 is formed with a claw 51a, a clearance 51b, a relief portion 51c, a protrusion 51d, a holding piece 51e and a protrusion 51f. This point is the same as in the case of the rotational biasing direction determination part 50.
In addition, the holding pieces 51e are formed at different positions in the circumferential direction from the protruding pieces 51d, and also the points at which the protrusions 51f are formed on the lower side of the front end portion of the holding piece 51e in the rotation direction The same as in the case of the biasing direction determination part 50.

  The rotation biasing direction determination unit 52a is formed on the cover member 52, and the rotation biasing direction determination unit 52a is configured to fit the cover member 52 to the trunk body 42. The point which protrudes to the front end in the rotational direction is the same as in the case of the rotational biasing direction determining part 50. Further, in the cover member 52, a cylindrical portion 52b, an arc-shaped wall 52c, a groove 52d, and an insertion port 52e are formed as in the case of the rotation biasing direction determination component 50.

8. Coupling of the barrel main body 42 and the rotation biasing direction determination part 50 or 500 When making the top toy 1 for clockwise rotation, the cylinder 51 of the rotation biasing direction determination part 50 is taken from the trunk piece 42A and the trunk piece 42B. It inserts in the hole 43 from the upper surface side of the trunk body 42 which becomes. Then, the cover member 52 is fitted to the trunk body 42.
Then, the rotation biasing direction determination portion 52 a of the cover member 52 protrudes from the front end portion of the arc slit 45 in the rotation direction of the top toy 1 and narrows the width of the arc slit 45. Thereafter, only the cylindrical body 51 is rotated using a rotating jig. Thus, the held piece 48 is held between the holding piece 51 e of the cylindrical body 51 and the cover member 52.
In addition, in the case of the top toy 1 for counterclockwise rotation, the cylindrical body 51 of the rotation biasing direction determination component 500 is inserted into the hole 43 from the upper surface side of the trunk body 42 composed of the trunk piece 42C and the trunk piece 42D. . Then, the cover member 52 is fitted to the trunk body 42. As a result, the rotation biasing direction determination portion 52 a of the cover member 52 protrudes from the front end portion of the arc slit 45 in the rotation direction of the top toy 1 and narrows the width of the arc slit 45. Thereafter, only the cylindrical body 51 is rotated using a rotating jig. Thus, the held piece 48 is held between the holding piece 51 e of the cylindrical body 51 and the cover member 52.
In this case, it is attempted to insert the cylindrical body 51 of the rotation biasing direction determination part 500 into the hole 43 from the upper surface side of the barrel main body 42 consisting of the shell pieces 42A and 42B, or the cylinder of the rotation biasing direction determination part 50 When the body 51 is to be inserted into the hole 43 from the upper surface side of the trunk body 42 composed of the trunk piece 42C and the trunk piece 42D, the arc-shaped wall 52c abuts on the projection 48a and the insertion is blocked.

Further, since the concave grooves 47, 47 are formed in the body piece 42B and the convex strips 46, 46 are formed in the body piece 42C, the body piece 42B and the body piece 42C can be coupled. In this case, as shown in FIG. 11, since there is no piece 48a that functions as a mounting prevention part in the body piece 42B and the body piece 42C, the rotation biasing direction determination component 50, 500 is selectively used as the body body 42. It can be worn on In FIG. 13, the cylindrical body 51 is removed to make the drawing easier to see.
The following effects can be obtained by providing the attachment blocking portion in this manner. That is, only one rotation biasing direction determination component 50 for rotation only can mount only one rotation piece 42A of the cylinder main body 42 to which only the rotation bias direction determination component 500 for rotation only can be mounted. By replacing with one body piece 42C, since it changes to the body main body 42 which can attach both of the rotation biasing direction determination parts 50 and 500, it can give an impression as if it was powered up by combining.

(Assembling method of top toy 1)
The shaft portion 10 and the flywheel 30 are assembled in a fitted state such that the protruding portion 16 of the shaft portion 10 matches the recessed portion 32 of the flywheel 30 from below. Next, this assembled body is brought close to the body 40, 400, etc. (hereinafter simply referred to as "body 40") from below.
Then, the tongue 33 of the flywheel 30 is inserted from below into one end of the arc-shaped slit 45 of the body 40. In this state, the claws 17 of the shaft portion 10 and the gap 51b of the body portion 40 coincide with each other. Thereafter, the shaft portion 10 of the assembled body is pressed to the body portion 40 side. Then, the flywheel 30 is pressed against the lower surface of the body 40. Further, the pressing member 18 is lowered while the spring 19 in the shaft portion 10 is contracted, and the claws 17 of the shaft portion 10 are relatively pushed up above the claws 51 a of the trunk portion 40. Then, the claws 51 a of the trunk 40 come under the claws 17 of the shaft 10. Then, when the shaft portion 10 is integrally rotated with the flywheel 30 in a predetermined direction (a direction opposite to the rotation direction of the piece toy 1), the claws 17 and the claws 51a are vertically overlapped. Then, when the hand is released from the shaft portion 10, the lower surface of the claw 17 of the shaft portion 10 and the upper surface of the claw 51a of the trunk portion 40 abut each other by the biasing force of the spring 19 in the shaft portion 10. This state is shown in FIG. As a result, the ridges 20 and the undulations 51 c mesh with each other, and the toy top 1 is assembled.

(How to play etc)
Subsequently, an example of how to play using the top toy 1 will be described.
In this case, charging (rotational urging) of the rotational force of the piece toy 1 is performed by the launcher 60 shown in FIG. The launcher 60 is internally provided with a disc (not shown), and the disc is biased in one rotational direction by a spiral spring (not shown), and a cord (not shown) wound around the disc is pulled by a handle 61 The disc is rotated, and the top holder 62 is rotated. The rotation of the top holder 62 is transmitted to the top toy 1 by the fork 63 provided to project downward, and causes the top toy 1 to rotate. In this case, the fork 63 is inserted into the arc-shaped slit 45 of the body 40. Then, the fork 63 is relatively moved toward the rotation urging direction determination unit 52a. Then, since the slit width is small at the portion where the rotation biasing direction determination portion 52a of the arcuate slit 45 is projected, the projection 63b provided on the inner wall of the fork 63 is below the rotation biasing direction determination portion 52a. Dive into. Thereby, the top toy 1 is supported by the launcher 60 and is prevented from falling off. By the way, if the fork 63 is in the place where the rotation urging direction determination part 52a does not protrude, not only the top toy 1 can not be rotationally urged in a desired rotation urging direction, but the top toy 1 drops out of the fork 63 .
Then, when the handle 61 of the launcher 60 is pulled out, the rotation of the disc and hence the top holder 62 is stopped while the top toy 1 is still rotated by the inertia force, so that the projection 63b is the rotation biasing direction determining portion 52a. The lower toy comes out from below, moves to the wide portion of the slit 45, and follows the slope of the fork 63, etc.

When the cotter toy 1 thus fired is rotated in a predetermined direction in a predetermined field and collides with the other cotter toy 1, the shaft 40 and the flywheel 30 rotate on the trunk 40 by the impact force due to the collision. A force acts in the opposite direction to the direction, whereby the body 40 rotates relative to the direction of rotation of the shaft 10 and the flywheel 30 in the opposite direction.
Then, the undulations 51 c on the lower surface of the body 40 and the ridges 20 change the meshing position as the shaft 10 rotates relative to the body 40. Then, when the locking release position is reached, the clearance 51b of the trunk 40 and the claws 17 of the shaft 10 coincide with each other so that the locking is released, and the biasing force of the spring 19 in the shaft 10 causes the trunk 40 and the flywheel 30 Separates from the shaft 10.

  In this top toy 1, when a collision with the other top toy occurs, the overhanging portion 44 of the trunk 40 applies a strong impact to the other top toy. In that case, in the piece toy 1, since the trunk body 42 has a divided structure and the trunk pieces constituting the trunk portion 40 can be rearranged, the form changes according to the coupling state, and the design and the attack Force changes. This form change includes material change, weight change, shape, pattern or color change.

As mentioned above, although this invention was demonstrated based on embodiment, this invention is not limited to this embodiment, It can not be overemphasized that a various deformation | transformation is possible.
For example, in the above-mentioned embodiment, although two concave grooves 47 were provided in one trunk piece and two convex stripes 46 were provided in the other trunk piece, you may provide one or three or more.
Further, as shown in FIG. 14, if one concave groove 47 and one convex stripe 46 are provided on one of the trunk pieces, and one concave groove 47 and one convex stripe 46 are also provided on the other trunk piece, Since any body piece can be mounted freely, more flexible rearrangement is possible.
Further, in the above embodiment, the mounting restriction portion (piece 48a) is provided, but if the mounting restriction portion is not provided, the rotation biasing direction determination component 50, 500 can be mounted on one trunk body, so Free reassignment is possible. In this case, one concave groove 47 and one convex stripe 46 may be provided in one of the body pieces, and one concave groove 47 and one convex stripe 46 may be provided in the other cylindrical piece.
Furthermore, in the above embodiment, the rotation biasing direction determination components 50, 500 are configured separately from the shaft portion 10, but may be integrated with the shaft portion 10.
In the above embodiment, the projection (protrusion) 63b provided on the inner wall of the fork 63 is inserted under the rotation biasing direction determination unit 52a, and the top toy 1 is supported by the launcher 60, for example. The top toy 1 may be held and supported by a plurality of forks 63 positioned in the narrow portion of the arc-shaped slit 45 without providing the protrusion 63 b.

One-piece toy 10 A shaft portion 40 A body portion 42 A body 42A A body piece 42B A body piece 42C A body piece 42D A body piece 45 An arc shaped slit 48 A sandwiched piece 50 A rotational biasing direction determining part 51 A cylindrical body 52a A rotational biasing direction determining portion 400 Torso 500 rotation biasing direction determination part

Claims (6)

The body is supported by the launcher, and is configured to be rotationally biased and launched, and the launcher enables the support at the time of the rotation bias by the launcher and determines the direction of the rotation bias by the launcher. In the top toy having the determination section,
The barrels are configured so as to be mutually coupled and releasably connected to each other and longitudinally split and split into two barrel pieces that constitute the barrel main body when coupled;
A rotation biasing direction determination component that is configured to be detachable from the barrel body and in which the rotation biasing direction determination portion is formed;
A top toy, wherein each of the two trunk pieces is configured to be interchangeable with an alternative trunk piece.   The top toy according to claim 1, wherein the rotation biasing direction determination component mediates the connection between a shaft and the trunk body.   The cylinder body is formed in an annular shape so as to have a hole in the center, and the rotation biasing direction determining part is partially inserted into the hole in the center of the cylinder body at the time of mounting. Top toy as described in.   The rotation biasing direction determining component includes a cylindrical body having an axis extending in the vertical direction and insertable into the central hole, and a cover member closing an upper opening of the cylindrical body. The top toy according to claim 3.   A pinching piece is attached to the outer periphery of the cylindrical body, and a pinched piece is attached to the inner periphery of the central hole of the barrel main body, and the rotation biasing direction determining component includes the cylindrical body in the barrel main body. The piece toy according to claim 4, characterized in that the piece is inserted into the hole and is rotated, so that the piece to be held is held between the holding piece and the cover member so as to be mounted on the trunk body.   An arc-shaped slit is formed in each of the two trunk pieces, into which the fork of the launcher is inserted when the Coma toy is urged to rotate, and the rotation-biasing direction determining unit corresponds to each of the arc-shaped slits. In the state in which the rotation biasing direction determining part is mounted on the cylinder main body, two of the rotation biasing direction determining portions are provided so as to protrude to predetermined positions in the corresponding arcuate slits. The top toy according to any one of claims 1 to 5, wherein the width of the arcuate slit is narrowed.

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