阅读说明：本技术 装配式球 (Assembled ball ) 是由 胁林和幸 内田润 胜田骏平 于 2020-03-10 设计创作，主要内容包括：本发明提供一种装配式球,其结构构件和装配工序简单化,并且具有适当的反弹性。装配式球(1)的特征在于,其具备具有圆周长度的长条形的多枚平板(100),多枚平板(100)在径向视图中以朝向外侧凸出的方式被组装,从而使整体基本上形成球体；其中,各平板(100)相对于其它多枚平板(100)在相互交叉的平板重复部位(14)重叠,平板重复部位(14)通过平板接合手段(15)而接合。(The invention provides a fabricated ball, which has simplified structural components and assembly processes and has proper rebound. The fabricated ball (1) is characterized by comprising a plurality of long-strip-shaped flat plates (100) with circumferential length, wherein the plurality of flat plates (100) are assembled in a manner of protruding towards the outer side in a radial view, so that the whole is basically formed into a sphere; wherein each flat plate (100) is overlapped with respect to the other plural flat plates (100) at the plate overlapping portion (14) which is mutually crossed, and the plate overlapping portion (14) is jointed by the plate jointing means (15).)

1. A fabricated ball, characterized in that,

it has a plurality of strip-shaped flat plates with circumferential length;

the plurality of flat plates are assembled in a manner of projecting outward in a radial view so as to form a sphere substantially as a whole; wherein the content of the first and second substances,

each of the flat plates is overlapped with other plural flat plates at plate overlapping portions which intersect each other, and the plate overlapping portions are joined by plate joining means.

2. The fabricated ball of claim 1,

wherein each flat plate includes a short plate divided in a circumferential direction;

each short plate includes a first end portion, a second end portion, and an intermediate portion therebetween, and the first end portion of the first short plate, the second end portion of the second short plate, and the center of the intermediate portion of the third short plate among the three short plates overlap as the plate overlapping portion.

3. The fabricated ball of claim 2,

it further comprises an embedded plate capable of being assembled on the plurality of flat plates;

the insertion plate includes a cover portion and a mounting portion protruding from an outer periphery thereof, the mounting portion is overlapped with an end portion of the short plate close to the middle portion, and the cover portion is joined by insertion plate joining means in a manner of filling at least one gap formed between the plurality of flat plates.

4. Fabricated ball according to claim 2 or 3,

each short plate has, as the plate joining means, a projection portion provided at the intermediate portion and projecting toward an inner surface side of the spherical body, and a plate hole portion; the plate hole portions are provided at the first end portion and the second end portion, and are configured to fit into the protruding portions.

5. The fabricated ball of claim 4,

the intermediate portion is provided with three of the protruding portions, and the first end portion and the second end portion are provided with one of the plate hole portions, respectively.

6. The fabricated ball of claim 3,

as the insertion plate joining means, the insertion plate has an insertion plate hole portion provided in the mounting portion.

7. The fabricated ball of claim 3,

the insertion plate is joined to the flat plate through a peripheral portion of the lid portion of the insertion plate and a space portion between the flat plates.

8. A fabricated ball, comprising:

a plurality of elongated plates having a circumferential length; and

an insert plate that can be assembled to the plurality of plates; wherein the content of the first and second substances,

the plurality of flat plates are assembled in a manner of projecting outward in a radial view so as to form a sphere substantially as a whole;

each plate is overlapped at the plate repeated part which is mutually crossed relative to other plates;

the insertion plate includes a cover portion and a mounting portion protruding from an outer periphery thereof, the mounting portion is overlapped with the flat plates, and the cover portion is joined by insertion plate joining means in a manner of filling at least one gap formed between the plurality of flat plates.

9. The fabricated ball of claim 8,

each flat plate includes short plates divided in the circumferential direction,

each short plate includes a first end portion, a second end portion, and an intermediate portion therebetween, and of the three short plates, the first end portion of the first short plate, the second end portion of the second short plate, and the center of the intermediate portion of the third short plate overlap as the plate overlapping portion;

the mounting portion of the insertion plate overlaps with an end portion of the short plate close to the intermediate portion.

10. The fabricated ball of claim 9,

each short plate has a protrusion portion provided at the intermediate portion and protruding toward an inner surface side of the spherical body;

as the insertion plate joining means, the insertion plate has an insertion plate hole portion provided in the mounting portion.

11. Fabricated ball according to any of claims 8-10,

the insertion plate is joined to the flat plate through a peripheral portion of the lid portion of the insertion plate and a space portion between the flat plates.

Technical Field

The invention relates to a fabricated ball.

Background

Conventionally, a ball injected with air has been generally used as a game or game ball. In contrast, in some cases, a fabricated ball without air injection is also used. For example, in a takraw ball used for sports, a ball woven in a cage shape is used, and in terms of material, a takraw ball is conventionally used, whereas a plastic ball is now used. In addition, as game balls, various assembly type balls have been proposed, which are mainly used for toys for children or toys which are assembled and played by children themselves.

For example, patent document 1 discloses a takraw ball having a uniform shape, weight, and outer diameter, which is formed by assembling (knitting) 6 sheets of synthetic resin sheets having a uniform shape and weight and grooves on the side edges for engagement, according to a predetermined rule. Patent document 2 discloses a soccer-type fitting ball in which hexagonal panels, insertion holes formed on opposite sides of the hexagonal panels, and insertion pins are inserted and fixed to each other, and a ball body is fitted into a soccer-type fitting ball, thereby allowing a user to enjoy a game of intelligence through fitting and removal, and contributing to development of intelligence and brain (see, for example, patent document 2).

Prior Art

Patent document

Patent document 1: japanese Utility model No. 3130771

Patent document 2: japanese Utility model No. 3019826

Disclosure of Invention

Technical problem to be solved by the invention

However, in patent document 1, there is a problem that the long plate-like structural member such as a synthetic resin member and the assembly step of knitting them are complicated and it is difficult to easily assemble the same. In addition, although patent document 2 considers the use for amusement, it has a problem that rebound is low and the amusement property as a ball is insufficient.

The present invention has been made in view of the above problems, and an object thereof is to provide a fitting ball having appropriate rebound resilience by simplifying a structural member and a fitting process.

Means for solving the problems

In order to achieve the above object, the present invention is grasped by the following configurations.

(1) One of the technical solutions of the present invention is an assembly type ball, which is characterized in that it has a plurality of elongated flat plates having a circumferential length; the plurality of flat plates are assembled in a manner of projecting outward in a radial view so as to form a substantially spherical body as a whole; wherein each plate is overlapped with other plates at plate overlapping portions which intersect each other, and the plate overlapping portions are joined by plate joining means.

In the first technical means, each flat plate may include a short plate divided in the circumferential direction; each short plate includes a first end portion, a second end portion, and an intermediate portion therebetween, and the centers of the first end portion of the first short plate, the second end portion of the second short plate, and the intermediate portion of the third short plate among the three short plates are overlapped as the plate overlapping portion.

In addition, the fabricated ball may further include an insertion plate that can be assembled to the plurality of flat plates; the insertion plate includes a cover portion and a mounting portion protruding from an outer periphery thereof, the mounting portion is overlapped with a near end portion of the intermediate portion of the short plate, and the cover portion is joined by insertion plate joining means so as to fill at least one gap formed between the plurality of flat plates.

Further, as the flat plate joining means, each short plate may have a projection portion and a flat plate hole portion, the projection portion being provided at the intermediate portion and projecting toward the inner surface side of the spherical body; the plate hole portions are provided at the first end portion and the second end portion, and are configured to fit into the protruding portions.

In addition, the intermediate portion may be provided with three of the protrusions, and the first end portion and the second end portion may be provided with one of the plate hole portions, respectively.

Further, as the insertion plate joining means, the insertion plate may have an insertion plate hole portion provided in the mounting portion.

The insertion plate may be joined to the flat plate through a gap between the peripheral edge of the lid portion of the insertion plate and the flat plate.

(2) The second technical scheme of the invention is an assembly type ball, which is characterized by comprising the following components: a plurality of elongated plates having a circumferential length; and an embedded plate which can be assembled to the plurality of flat plates; wherein the plurality of flat plates are assembled in a manner of projecting outward in a radial view, so that the whole is basically formed into a sphere; each plate is overlapped at the plate repeated part which is mutually crossed relative to other plates; the insertion plate includes a cover portion and a mounting portion protruding from an outer periphery thereof, the mounting portion is overlapped with the flat plates, and the cover portion is joined by insertion plate joining means so as to fill at least one gap formed between the plurality of flat plates.

In the second aspect, each flat plate may include short plates divided in the circumferential direction, each short plate may include a first end portion, a second end portion, and an intermediate portion therebetween, and the centers of the first end portion of the first short plate, the second end portion of the second short plate, and the intermediate portion of the third short plate among the three short plates may overlap as the flat plate overlapping portion; the mounting portion of the insertion plate overlaps with an end portion of the short plate near the intermediate portion.

Further, each short plate may have a protrusion provided in the intermediate portion and protruding toward the inner surface side of the spherical body; the insertion plate has an insertion plate hole portion provided in the mounting portion as the insertion plate joining means.

The insertion plate may be joined to the flat plate through a gap between the peripheral edge of the lid portion of the insertion plate and the flat plate.

Effects of the invention

According to the present invention, it is possible to provide a fabricated ball having appropriate rebound properties while simplifying the structural members and the fabrication process.

Drawings

Fig. 1 is a front view showing a fabricated ball according to a first embodiment of the present invention, and shows a form of being constituted only by a flat plate.

Fig. 2 is a front view of a fabricated ball according to a first embodiment of the present invention, and shows a configuration including a flat plate and an insertion plate.

Fig. 3 is a diagram (1) showing a fitting process of a fitting ball according to a first embodiment of the present invention.

Fig. 4 is a diagram (2) showing a fitting process of a fitting ball according to a first embodiment of the present invention.

Fig. 5 is a diagram (fig. 3) showing a fitting process of a fitting ball according to the first embodiment of the present invention.

Fig. 6 is a diagram illustrating a protrusion provided on a flat plate (short plate) according to a first embodiment of the present invention, fig. 6(a) is a diagram illustrating a two-strand protrusion, and fig. 6(b) is a diagram illustrating a three-strand protrusion.

Fig. 7 is a diagram illustrating an insertion plate according to a first embodiment of the present invention, fig. 7(a) is a diagram illustrating a cover portion and a mounting portion integrally formed, and fig. 7(b) is a diagram illustrating a cover portion and a mounting portion separately formed.

Fig. 8 is a front view of a fabricated ball according to a second embodiment of the present invention, and shows a configuration including a flat plate and an insertion plate.

Fig. 9 is an external view showing an enlarged description of the relationship between the insertion plate and the flat plate (short plate) in fig. 8.

Fig. 10 is a view showing that the cover portion and the mounting portion of the insertion plate according to the second embodiment of the present invention are formed separately.

Fig. 11 is a sectional view showing a relationship between the insertion plate and the flat plate (short plate) in fig. 9.

Detailed Description

Hereinafter, a mode for carrying out the present invention (hereinafter, referred to as "embodiment") will be described in detail with reference to the drawings. In the description of the embodiments, the same elements will be denoted by the same reference numerals.

(first embodiment)

As shown in fig. 1, a fabricated ball 1 according to the first embodiment includes a plurality of long-strip-shaped flat plates 100 having a circumferential length, and the plurality of flat plates 100 are assembled to be convex outward in a radial view, so that the entirety is substantially formed into a spherical body; each flat plate 100 is overlapped with other plural flat plates 100 at the plate overlapping portion 14 which is mutually crossed, and the plate overlapping portion 14 is joined by the plate joining means 15.

The flat plate 100 may be a flat plate having a smooth shape or a curved flat plate previously curved in an R shape in the longitudinal direction. In the former case, the flat plate 100 is assembled by being smoothly bent in the longitudinal direction so as to project toward the outside in a radial view; in the latter case, the flat plate 100 is assembled by positioning the R shape in the longitudinal direction thereof so as to project toward the outside in a radial view. Here, the flat plate 100 may be previously bent in an R shape in a transverse direction in addition to or instead of the longitudinal direction. When the flat plate 100 is bent in at least one of the longitudinal direction and the lateral direction, the assembly becomes easy, and the outer surface of the assembled fabricated ball 1 becomes smoother after the assembly, so that better rebound can be obtained. Especially for transverse directions, which are difficult to bend at assembly, pre-bending is advantageous. Further, the flat plates 100 may overlap at adjacent plate repeat locations 14, in a radial view, in an outer and inner repeat manner, or on either side of the outer and inner sides, relative to other pluralities of flat plates 100.

Although fig. 1 shows an example of a fabricated ball 1 formed of six flat plates 100, the number of flat plates is not limited to this, and a fabricated ball 1 may be formed of, for example, ten flat plates 100.

The flat plate 100 may be formed of one piece alone to have the circumferential length of the fabricated ball 1, or may be formed by joining short plates 10 divided in the circumferential direction to have the circumferential length as a whole. In this case, as will be described later, each short plate 10 includes a first end portion 11, a second end portion 12, and an intermediate portion 13 therebetween, and in three short plates 10 out of the plurality of short plates 10, the first end portion 11 of the first short plate 10, the second end portion 12 of the second short plate 10, and the center of the intermediate portion 13 of the third short plate 10 are overlapped as a plate overlapping portion 14, and the plate overlapping portion 14 is joined by a plate joining means 15. Hereinafter, the fabricated ball 1 formed using the short plates 10 will be described, but the description is also applicable to the fabricated ball 1 formed using the flat plate 100 in which the flat plate 100 is formed by connecting the short plates 10 in the circumferential direction.

Although fig. 1 shows an example in which flat plate 100 is divided into four short plates 10, the number of the short plates is not limited to this, and flat plate 100 may be divided into six short plates 10, for example.

The fitting ball 1 is configured by fitting a plurality of short plates 10, and the fitting details will be described later, and here, 5 long short plates 10a, 10b, 10c, 10d, and 10e will be described. In addition, the plurality of short plates 10 have the same structure, and the symbols 10a, 10b, 10c, 10d, and 10e shown here are given for convenience of explanation. Therefore, the plurality of short plates 10 having the same relative positional relationship with them have the same structure. Further, when common matters of the respective short plates 10 are described, they may be simply referred to as the short plates 10.

The short plate 10 includes a first end portion 11 and a second end portion 12 opposite to the first end portion, and an intermediate portion 13 therebetween, and the second end portion 12 of the short plate 10e is overlapped as a plate overlapping portion 14 at the center of the intermediate portion 13 of the short plate 10a, the second end portion 12 of the short plate 10a is at the center of the intermediate portion 13 of the short plate 10b, the second end portion 12 of the short plate 10b is at the center of the intermediate portion 13 of the short plate 10c, the second end portion 12 of the short plate 10c is at the center of the intermediate portion 13 of the short plate 10d, and the second end portion 12 of the short plate 10d is at the center of the intermediate portion 13 of the short plate 10e, respectively. At this time, the short plates 10a, 10b, 10c, 10d, 10e are assembled in such a manner as to project outward in a radial view, so that the entirety is substantially formed into a sphere.

Here, the short plate 10 may be a flat plate having a smooth shape, or a curved flat plate previously curved in an R shape in the longitudinal direction, similarly to the flat plate 100. In the former case, the short plate 10 is assembled by being smoothly bent in the longitudinal direction so as to project toward the outside in a radial view; in the latter case, the short plate 10 is assembled by positioning the R shape in the longitudinal direction thereof so as to project toward the outside in a radial view. Here, the short plate 10 may be previously bent in an R shape in the transverse direction in addition to the longitudinal direction, or instead of the longitudinal direction. When the short plate 10 is bent in at least one of the longitudinal direction and the lateral direction, the assembly becomes easy, and the outer surface of the assembled fitting ball 1 becomes smoother after the assembly, so that better rebound can be obtained. Especially for transverse directions, which are difficult to bend at assembly, pre-bending is advantageous. Further, the short plates 10 may overlap at adjacent plate repeat locations 14, in a radial view, in an outer and inner repeat manner, or on either side of the outer and inner sides, relative to other plural short plates 10.

By assembling the short plates 10a, 10b, 10c, 10d, and 10e in this way, a pentagonal gap G1 is formed inside the short plates 10a, 10b, 10c, 10d, and 10 e. A small gap G2 is formed between adjacent short plates 10 on the outer side of the short plates 10a, 10b, 10c, 10d, 10 e.

The overlapping of the plate overlapping portions 14 is performed such that the middle portion 13 of each short plate 10 is positioned on the outer surface side of the fabricated ball 1 and the first end portion 11 and the second end portion 12 of each short plate 10 are positioned on the inner side of the fabricated ball 1.

The plate overlapping portion 14 is fixed at one point by penetrating the centers of the first end portion 11, the second end portion 12, and the intermediate portion 13 of the three overlapped short plates 10 by plate joining means 15. As the plate joining means 15, as described later, the projection 16 may be provided in the middle portion 13 of the short plate 10, and the plate hole 17 may be provided in the first end portion 11 and the second end portion 12, and in addition, the plate joining means may be bonded by an adhesive, or fixed by a rivet, a screw, or the like.

In the fabricated ball 1 configured as described above, by fixing the intersection point (the flat plate overlapping portion 14) where the three short plates 10 are overlapped at one point and assembling the short plates 10 having the same shape so as to protrude outward in a radial view, elasticity can be obtained and appropriate rebound resilience can be secured.

The fabricated ball 1 may further include an insertion plate 20 to be assembled to the plurality of short plates 10 as shown in fig. 2, and as shown in fig. 3(a), the insertion plate 20 may include a cover portion 21 and a mounting portion 22 protruding from an outer periphery thereof, the mounting portion 22 may be overlapped with a near end portion of the intermediate portion 13 of the plurality of short plates 10, and the cover portion 21 may be joined by insertion plate joining means 23 so as to fill at least one gap G formed between the plurality of short plates 10.

The insertion plate 20 has an insertion plate hole portion 23 provided in the mounting portion 22 as insertion plate joining means 23.

The insert plate 20 is assembled to at least one gap G1 of the above-described gaps G1 and G2. As will be described later, the gap G1 formed by the short plates 10a, 10b, 10c, 10d, 10e is filled with the insertion plate 20, whereby the elasticity of the short plates 10a, 10b, 10c, 10d, 10e can be made uniform and the effect of the stabilizer can be exerted.

In fig. 2, the insertion plate 20 at the upper center is cut away to show the gap G1 for the sake of explanation.

Next, the assembling process of the assembled ball 1 will be described with reference to fig. 3 to 5.

First, the short plate 10 and the insertion plate 20 will be described again with reference to fig. 3 (a). The shorting plate 10 includes a first end portion 11, a second end portion 12, and an intermediate portion 13. As the flat plate joining means 15, the short plate 10 has a projection 16 and a flat plate hole 17, wherein the projection 16 is provided in the intermediate portion 13 and projects toward the inner surface side of the sphere; the plate hole portions 17 are provided in the first end portion 11 and the second end portion 12, and fit into the protrusion portions 16. Here, an example is shown in which the protrusion 16 is provided at three positions (the center protrusion 161, the protrusion 162 near the first end, and the protrusion 163 near the second end), and an example is shown in which the flat hole portion 17 is provided at each of the first end 11 and the second end 12.

The insertion plate 20 includes a lid 21 and a mounting portion 22 protruding from the outer periphery thereof. Here, the cover 21 is formed in a pentagon shape so as to match the shape of the gap G1, and five mounting portions 22 are provided corresponding to the respective sides. Each mounting portion 22 is provided with an insertion hole portion 23 into which the projection portion 16 of the short plate 10 is inserted.

Although the process of assembling the fabricated ball 1 using both the short plate 10 and the insertion plate 20 will be described below, when the assembled ball is assembled using only the short plate 10, the insertion plate 20 does not need to be assembled.

First, as shown in fig. 3 b, 5 short plates 10a, 10b, 10c, 10d, 10e are stacked, as described above, such that the second end portion 12 (12 e in the drawing) of the short plate 10e is overlapped at the center of the intermediate portion 13 (13 a in the drawing) of the short plate 10a, the second end portion 12 (12 a in the drawing) of the short plate 10a is overlapped at the center of the intermediate portion 13 of the short plate 10b, the second end portion 12 of the short plate 10b is overlapped at the center of the intermediate portion 13 of the short plate 10c, the second end portion 12 of the short plate 10c is overlapped at the center of the intermediate portion 13 of the short plate 10d, and the second end portion 12 of the short plate 10d is overlapped at the center of the intermediate portion 13 (13 e in the drawing) of the short plate 10e as the plate overlap portion 14, to form a base of the fabricated ball 1. At this time, for example, in the two-plate overlapped portion 14 of the short plate 10a and the short plate 10e, the projection 161 (161 a in the figure) at the center of the middle portion 13 (13 a in the figure) of the short plate 10a overlaps the plate hole portion 17 (17 e in the figure) of the second end portion 12 (12 e in the figure) of the short plate 10 e.

Next, as shown in fig. 3(c), 5 sets of two short plates 10 are prepared, and the two short plates 10 are combined by overlapping the projection 161 at the center of the intermediate portion 13 of one short plate 10 with the flat hole 17 at the second end portion 12 of the other short plate 10. As shown in fig. 3(d), for example, a group of short plates 10f and 10g among these groups is assembled to the base of fig. 3 (b). That is, the second end portion 12 (12 f in the figure) of the short plate 10f is overlapped on the center of the intermediate portion 13 (13 a in the figure) of the short plate 10a and the plate overlapping portion 14 of the second end portion 12 (12 e in the figure) of the short plate 10e, and the center of the intermediate portion 13 (13 f in the figure) of the short plate 10f and the plate overlapping portion 14 of the second end portion 12 (12 g in the figure) of the short plate 10g are overlapped on the first end portion 11 (11 b in the figure) of the short plate 10b, respectively. As a result, as shown in fig. 3(e), the plate hole 17f of the second end portion 12 (12 f in the figure) of the short plate 10f is overlapped again on the plate overlapping portion 14 of the two short plates of the short plate 10a and the short plate 10e, and the three short plates 10 are assembled together.

Then, as shown in fig. 3(f), one short plate 10, for example, 10i is assembled. That is, the second end portion 12 (12 i in the figure) and the first end portion 11 (11 i in the figure) of the short plate 10i are connected to each other at the center of the intermediate portion 13 (13 h in the figure) of the short plate 10h adjacent to each other in fig. 3f and the first end portion 11 (11 f in the figure) of the short plate 10f, and then assembled, as shown in fig. 4 a, the two adjacent short plates 10 are connected to each other. This process is repeated to form a stage of fig. 4(b), and the lower half of fabricated ball 1 is formed. At this stage, as shown in fig. 4(c), the embedded plate 20 is mounted. Then, as shown in fig. 4(d) to 4(f), a set of two short plates 10 is assembled in order to form the upper half of the fabricated ball 1. In fig. 4(a) to 4(f) (including fig. 5(a) to 5(e)), the protrusion 16 is omitted.

As shown in fig. 5(a) and 5(b), the insertion plate 20 is assembled in order along with the formation of the upper half. Fig. 5(c) to 5(e) are diagrams showing a process of installing the final embedded plate 20. The final insert plate 20 is assembled to the short plate 10 as much as possible before closing the fabricated ball 1, and finally, the protrusion 16 of the short plate 10 is inserted into the insert plate hole portion 23 of the mounting portion 22 of the insert plate 20 by inserting the tool D into the adjacent gap G2.

In the above process, the insertion plate hole portion 23 of the attachment portion 22 of the insertion plate 20 is assembled to the projection portion 162 near the first end or the projection portion 163 near the second end among the projection portions 16 of the short plate 10. In other words, since the points in the plate joining means 15 adjacent to the plate repeat portion 14 are fixed to each other, it is possible to uniformize the elasticity of the fabricated ball 1 and exhibit the stabilizer effect as described above.

Furthermore, the short plate 10 may be modified to provide a groove portion between the intermediate portion 13, the first end portion 11, and the second end portion 12. The first end portion 11 and the second end portion 12 can be flexibly moved relative to the intermediate portion 13 by the recessed portions, and the assembled structure can be easily assembled and the rebound resilience of the assembled fabricated ball 1 can be adjusted.

Next, the protrusion 16 provided on the short plate 10 will be described with reference to fig. 6. As described above, the plate joining means 15 may be by adhesion, or by such as rivet, screw fixation, or the like, but for easy manual assembly, it is preferable to use the embedding of the protruding portion 16 into the plate hole portion 17 or the embedded plate hole portion 23. Fig. 6(a) shows an example of the protrusion 16, which includes a flared portion 164, an overhanging portion 165, and a narrowed portion 166 expanding in two strands toward the root. The expanded portion 164 is formed to be flexible, and when fitted into the plate hole portion 17 or the fitted plate hole portion 23, the plate hole portion 17 or the fitted plate hole portion 23 passes over the overhanging portion 165 and engages with the narrowed portion 166.

Fig. 6(b) shows a protrusion 16A as another example of the protrusion 16, which includes a flared portion 164, an overhanging portion 165, and a narrowed portion 166 that are expanded toward the root in a three-strand shape. The projection 16A is a more suitable pattern than the projection 16 because it is not easily detached once it is fitted into the plate hole portion 17 or the plate hole portion 23.

The insertion plate 20 will be described with reference to fig. 7. Fig. 7(a) shows a view in which the above-described insertion plate 20, cover portion 21, and mounting portion 22 are integrally formed.

Fig. 7(b) shows an insertion plate 20A as another example of the insertion plate 20, of which a cover portion 211 and a mounting portion 222 are separately formed. Specifically, the mounting portion 222 having the insertion hole 231 is provided around the annular portion 221 separated from the cover portion 211. Further, a groove portion 223 is provided between the annular portion 221 and the mounting portion 222. In this way, since the annular portion 221 and the mounting portion 222 are formed to have flexibility, they are easily mounted to the inside of the fitting ball 1 at the time of fitting. After the outer shell of the fabricated ball 1 is completed, the cover portion 211 is fitted into the annular portion 221. The cover 211 has an engaging portion 212 at its base portion, which is movable forward and backward, and the engaging portion 212 is moved backward toward the base portion when fitted, and is engaged with the annular portion 221 by protruding after fitting. The peripheral edge portion 211a of the cover portion 211 is configured to cover the groove portion 223 when the cover portion 211 is fitted into the annular portion 221, and is located at a position substantially in contact with the short plate 10 in the fabricated ball 1 (see fig. 2).

(second embodiment)

Next, the fitting ball 1 according to the second embodiment will be described. The fitting ball 1 according to the second embodiment is formed in the same configuration as that of the first embodiment except that the insertion plates 20 and 20A are replaced with the insertion plate 30A, and therefore, the insertion plate 30A will be described below.

In the fabricated ball 1 according to the first embodiment, although the peripheral edge portion 211a of the lid portion 211 of the insertion plate 20A is located at the same height as the short plate 10 and is substantially in contact therewith, since the fabricated ball is not completely connected, if the fabricated ball is used vigorously, such as a barefoot kick or a bare-hand hit, the exposed skin of the user's feet, hands, etc. may be caught in the gap between the peripheral edge portion 211a and the short plate 10, which may cause a negative injury associated with pain or bleeding. The second embodiment is for suppressing such possible pain or negative injury, and is constituted as follows.

In the fabricated ball 1 according to the second embodiment, as shown in fig. 8 and 9, the insertion plate 30A is joined to the short plate 10 via the prominent spacers 324, 323, and 325 between the peripheral edge 311a of the lid portion 311 of the insertion plate 30A and the short plate 10. As will be described later, the spacer portions 324, 323, 325 are formed by a part of the mounting portion 322 of the insertion plate 30A, and are exposed without being covered with the peripheral edge portion 311a of the lid portion 311.

As shown in fig. 10, the insertion plate 30A is configured such that the cover portion 311 and the attachment portion 322 are formed separately, and the aforementioned spacing portions 324, 323, and 325 are formed by the wide root portion 324 of the attachment portion 322, the connection portion 325 connected to the annular portion 321, and the groove portion 323 between the wide root portion 324 and the connection portion 325. A cross-sectional view thereof is shown in fig. 11. That is, the annular portion 321 of the mounting portion 322 is fitted between the peripheral portion 311a of the cover portion 311 and the engaging portion 312 provided at the base portion so as to be movable forward and backward. The attachment portion 322 is engaged with the protrusions 16 and 16A of the short plate 10 through the insertion plate hole 331 (see fig. 10) via a connection portion 325 extending outward from the annular portion 321, a recessed groove 323 provided to descend from the connection portion 325, and a wide root portion 324 provided to ascend from the recessed groove 323. Here, the cover portion 311 and the short plate 10 are set to have substantially the same height, and the wide root portion 324, the groove portion 323, and the connection portion 325 of the mounting portion 322 are positioned so as to have a low step corresponding to at least the thickness of the cover portion 311 or the short plate 10.

In this way, by providing the spacing portions 324, 323, 325 between the peripheral edge 311a of the cover portion 311 of the insertion plate 30A and the short plate 10 and setting the spacing portions 324, 323, 325 lower than the cover portion 311 or the short plate 10, even if the fabricated ball 1 is deformed when kicking a ball with bare feet or hitting a ball with bare hands, the skin or the like is not sandwiched between the peripheral edge 311a of the cover portion 311 and the short plate 10, and the fabricated ball 1 having a good kick feeling can be provided.

Note that, although the second embodiment describes the insertion plate 30A in which the cover portion 311 and the mounting portion 322 are formed separately from each other in correspondence with the insertion plate 20A of the first embodiment, the insertion plate in which the cover portion 311 and the mounting portion 322 are formed integrally may be provided with the spacer portions 324, 323, 325, similarly to the insertion plate 20. Although the spacer portions 324, 323, and 325 are positioned so as to have a low step corresponding to at least the thickness of the cover portion 311 or the short plate 10, that is, so as to be entirely concave when viewed from the cover portion 311 or the short plate 10, the spacer portions 324, 323, and 325 only need to be able to be significantly separated from each other at a height different from the height of the cover portion 311 and the short plate 10, and therefore may have a convex shape protruding entirely when viewed from the cover portion 311 or the short plate 10. Further, although the embedded plate including the concave groove portion 323 has been described, a convex peak portion may be included instead of the concave groove portion 323 or in addition to the groove portion 323.

The dimensions of the spacers 324, 323, 325 are different depending on the design, size, and the like of the fabricated ball 1, and therefore are not limited to the following values, and only one suitable example is shown below. In a test of kicking a ball with bare feet by a fabricated ball 1 fabricated using the insert plate 30A, if the distance between the peripheral edge 311a of the lid portion 311 of the insert plate 30A and the spacers 324, 323, 325 of the short plate 10 is in the range of 0 (which cannot be completely 0 because of the fabricated type) to 6mm, the skin or the like may be "pinched". Although the "sandwiched" condition does not occur when the distance is 7mm or more, the distance between the spacing portions 324, 323, 325 is set to 8mm or more in consideration of the assembling deviation of the respective members.

The heights of the spacer portions 324, 323, and 325 of the fabricated ball 1 used in the test were set to be lower than the height difference corresponding to the thickness (about 1mm) of the cap portion 311 of the insertion plate 30A and the upper surface of the short plate 10.

(modification example)

In the first and second embodiments described above, the fitting ball 1 is configured by fixing the plate overlapping portions 14 between the short plates 10 (or the plates 100) by the plate joining means 15, and the insertion plate 20 can be further attached when it is necessary to balance the elasticity of the short plates 10 (or the plates 100) to exhibit the effect of a stabilizer. On the other hand, the fitting ball 1 (see fig. 2) may be configured by fixing the insertion plate 20 to a plurality of short plates 10 (or plates 100) by the insertion plate joining means 23, instead of fixing the plate overlapping portions 14 between the short plates 10 (or plates 100) by the plate joining means 15. Thus, the fabricated ball 1 having the insertion plate 20 which exhibits the effect of a stabilizer by equalizing the elasticity of the short plate 10 (or the flat plate 100) can be obtained by a simpler process.

That is, the fabricated ball 1 according to the modification includes a plurality of long flat plates 100 having a circumferential length and the insertion plate 20 assembled to the plurality of flat plates 100, and the plurality of flat plates 100 are assembled to project outward in a radial view so that the entire body is substantially formed as a sphere, and the flat plates 100 are overlapped with the other plurality of flat plates 100 at the plate overlapping portions 14 intersecting with each other; the insertion plate 20 includes a lid portion 21 and a mounting portion 22 protruding at the outer periphery thereof, and the mounting portion 22 and the flat plate 100 are overlapped; the lid 21 is joined by a fitting plate joining means 23 so as to fill at least one gap formed between the plurality of flat plates 100.

The flat plate 100 may be formed of one piece alone to have the circumferential length of the fabricated ball 1, or may be formed by connecting short plates 10 divided in the circumferential direction to have the circumferential length as a whole, similarly to the first and second embodiments described above. In this case, each short plate 10 includes a first end portion 11, a second end portion 12, and an intermediate portion 13 therebetween, and among the three short plates 10, the first end portion 11 of the first short plate 10, the second end portion 12 of the second short plate 10, and the intermediate portion 13 of the third short plate are overlapped as a plate overlapping portion 14, and the attachment portion 22 of the insertion plate 20 is overlapped with the end portion of the short plate 10 close to the intermediate portion 13.

When the insertion plate 20 and the short plate 10 are fixed, similarly to the first and second embodiments, each short plate 10 may have a protrusion 16 provided on the intermediate portion 13 and protruding toward the inner surface side of the sphere, and the insertion plate 20 may have an insertion plate hole portion 23 provided on the mounting portion 22 as the insertion plate engagement means 23.

The present invention has been described above using the first embodiment, the second embodiment, and the modified examples, but the technical scope of the present invention is not limited to the scope described in the first embodiment and the second embodiment. It will be apparent to those skilled in the art that various changes and modifications can be made to the first and second embodiments described above. It is apparent from the description of the claims that such modifications and improvements can be included in the technical scope of the present invention.

Description of the symbols

1 assembled ball

10. 10A short board

100 flat plate

11 first end portion

12 second end portion

13 middle part

14 plate repeat

15 flat plate joining means

16. 16A projection

161 (central) projection

162 (near the first end portion)

163 (near the second end) protrusion

164 (of the projection) flared

165 (of the projection) extension

166 (of the projection) narrow part

17 flat hole part

20. 20A, 30A embedded plate

21 cover part

22 mounting part

23 inserting plate hole part (inserting plate jointing means)

211 cover part

211a (of the lid part) peripheral edge part

212 engaging part

221 annular part

222 mounting part

223 groove part

231 is inserted into the plate hole

311 cover part

311a (of the lid part)

312 engaging part

321 annular part

322 mounting part

323 groove part (spacing part)

324 wide root (spacer)

325 connecting part (spacer part)

331 is inserted into the plate hole portion