CN115430159A

CN115430159A - Toy component and model toy

Info

Publication number: CN115430159A
Application number: CN202211088488.9A
Authority: CN
Inventors: 林田翔一; 生頼卓也
Original assignee: Bandai Co Ltd
Current assignee: Bandai Co Ltd
Priority date: 2022-03-11
Filing date: 2022-09-07
Publication date: 2022-12-06
Anticipated expiration: 2042-09-07
Also published as: JP2023133061A; CN115430159B; CN117771687A; JP7093904B1; JP2023132859A

Abstract

The present invention relates to a toy component and a model toy. A toy component of a hand which makes the grasping of the hand more natural. A toy member which is a toy member of a hand of a model toy, wherein the toy member comprises: a plurality of 1 st finger structures each configured to be bendable toward the 1 st surface of the toy member; a 1 st member to which the 1 st finger structures are rotatably connected; a 2 nd member, the 1 st member being rotatably connected to the 2 nd member; a 1 st cover member coupled to a 2 nd surface side of the 2 nd member opposite to the 1 st surface; and a 2 nd cover member rotatably connected to the 1 st cover member.

Description

Toy component and model toy

Technical Field

The present invention relates to a toy component and a model toy.

Background

Patent document 1 describes a hand structure as a toy component of a built-up toy. In the toy component, a part of the palm is integrally formed.

Documents of the prior art

Patent document

Patent document 1: japanese laid-open patent publication No. 2009-107275

Disclosure of Invention

Problems to be solved by the invention

An object of the present invention is to provide a toy component of a hand that makes the expression of the grip of the hand more natural than the toy component described in patent document 1.

Means for solving the problems

The present invention is a toy component of a hand of a model toy, the toy component comprising: a plurality of 1 st finger structures each configured to be bendable toward the 1 st surface of the toy member; a 1 st member to which the 1 st finger structures are rotatably connected; a 2 nd member, the 1 st member being rotatably connected to the 2 nd member; a 1 st cover member coupled to a 2 nd surface side of the 2 nd member opposite to the 1 st surface; and a 2 nd cover member rotatably connected to the 1 st cover member, wherein the toy part of the hand has a 1 st state in which the hand is opened and a 2 nd state in which the hand is closed, and the 1 st member and the 2 nd cover member are configured to be rotatable toward the 1 st surface side in accordance with bending of the plurality of 1 st finger structures toward the 1 st surface side in the 2 nd state.

In addition, the present invention is a model toy having the above-described toy components.

ADVANTAGEOUS EFFECTS OF INVENTION

The invention provides a toy component of a hand and a model toy using the toy component, wherein the toy component can make the grasping of the hand more natural.

Drawings

Fig. 1 is a diagram showing an example of an appearance of a built-up toy according to an embodiment.

Fig. 2 is a view showing an example of an appearance of a toy member according to embodiment 1 in the 1 st state.

Fig. 3 is a diagram showing an example of an appearance of a toy member according to embodiment 2 in a state 2.

Fig. 4 is a diagram showing an example of an exploded structure of the 1 st surface of a toy component according to the embodiment.

Fig. 5 is a diagram showing an example of an exploded structure of the 2 nd surface of a toy member according to the embodiment.

Fig. 6 is a view showing an example of a cross-sectional structure of a toy member according to embodiment 1 in the first state.

Fig. 7 is a view showing an example of a cross-sectional structure of a toy member according to embodiment 2.

Detailed Description

Hereinafter, embodiments will be described in detail with reference to the drawings. The following embodiments are not intended to limit the invention claimed in the claims, and all combinations of the features described in the embodiments are not essential to the invention. Two or more of the plurality of features described in the embodiments may be arbitrarily combined. The same or similar components are denoted by the same reference numerals, and redundant description thereof is omitted. In the drawings, the vertical, horizontal, and front-back directions with respect to the paper surface are used as the vertical, horizontal, and front-back directions of the member (or the metal fitting) in the present embodiment.

First, as a model toy corresponding to the present embodiment, fig. 1 shows an example of an appearance of a doll-type assembled toy. Fig. 1 is a schematic view showing an appearance of a built-up toy 1 of the embodiment in a simplified manner. The assembled toy 1 has model members of a head 10, a torso 11, arms 12, a waist 13, and legs 14, and is configured by joining them. Further, a hand corresponding to the toy member 100 of the present embodiment is coupled to the tip of the arm portion 12. In the present embodiment, an example of an assembled toy in which model members are assembled by a user is described as a model toy, but the present invention is not limited to this, and an assembled model toy may be used.

At least a part of each of the portions 10 to 14, 100 is supported to be rotatable (or swingable) with respect to an adjacent portion. For example, the head section 10 is supported to be rotatable with respect to the body section 11, and the arm section 12 is supported to be rotatable, tiltable forward, and tiltable backward with respect to the body section 11. The toy component 100 is also supported for rotation relative to the arm 12.

In this manner, joint structures are provided at respective portions of the assembled toy 1, and a user (for example, the owner of the assembled toy 1) can set the assembled toy 1 in a desired posture. In fig. 1, one or more decorative members may be attached to the assembly toy 1, although not shown. The decorative member can also be configured in the same manner as the model member of the assembled toy described in the present embodiment. Examples of the decorative member include weapons such as a sword and a gun, and protectors such as a shield. According to the toy component 100 of the present embodiment, such a weapon or a tool can be gripped, and the appearance of the toy component 100 when gripping a weapon or the like can be made more natural.

Next, fig. 2 and 3 show an example of a more detailed appearance of a toy component according to the present embodiment. In the present embodiment, the toy component 100 of the hand in which the toy 1 is assembled is referred to as "state 1" in which the hand is opened, and as "state 2" in which the hand is closed. Fig. 2 shows an example of the appearance of the toy part 100 in the 1 st state, and fig. 3 shows an example of the appearance of the toy part 100 in the 2 nd state. In the state 1 of the toy member 100, the palm side is referred to as "the 1 st surface", and the back side is referred to as "the 2 nd surface".

Fig. 2 (a) is a view showing the appearance of the 1 st surface side of the toy member 100 of the hand of the assembled toy 1 according to the embodiment. Fig. 2 (B) is a view showing the appearance of the 2 nd surface side of the toy component 100. In fig. 2, the toy component 100 includes a plurality of finger structures corresponding to a thumb 101, an index finger 102, a middle finger 103, a ring finger 104, and a little finger 105. Here, the number of fingers can be varied according to the structure of the assembled toy 1.

Each finger structure has 1 st to 3 rd joint parts and can be bent to the 1 st surface side. The palm portion is formed of two

fittings

106 and 107, and the fitting 106 and the fitting 107 are connected to each other so as to be rotatable in the inner direction of the palm (direction toward the 1 st surface side). The index finger part 102, the middle finger part 103, the ring finger part 104, and the small finger part 105 are connected to the attachment 106 so as to be rotatable at least toward the 1 st surface side, and the thumb part 101 is connected to the attachment 107 so as to be rotatable in the directions of

arrows

201 and 202. Here, the index finger 102, the middle finger 103, the ring finger 104, and the small finger 105 connected to the metal fitting 106 can be referred to as "1 st finger structure"(s) and the thumb 101 connected to the metal fitting 107 can be referred to as "2 nd finger structure" depending on the connection destination of each finger structure. The joint 111 constituting the wrist is rotatably connected to the attachment 107, and can be connected to the arm 12 of the assembled toy 1 via the joint 111.

Further, on the 2 nd surface side of the toy member 100, the metal fitting 108 and the metal fitting 109 are disposed so as to cover the metal fitting 106 and the metal fitting 107, and the metal fitting 108 is connected to the metal fitting 109 so as to be rotatable toward the 1 st surface side with respect to the metal fitting 109. The metal fitting 106 and the metal fitting 108 are not directly connected, but when the metal fitting 106 is bent toward the palm, the metal fitting 108 can be bent together. Further, the operation of the fitting 108 may be interlocked with the fitting 106. The

fittings

107 and 109 function as bases when the finger structure and the fittings 106 rotate.

Next, fig. 3 (a) is a diagram showing the appearance of the 1 st surface side of the toy member 100 in the case where the plurality of finger structures are bent to the 2 nd state according to the embodiment. Fig. 3 (B) is a view showing the appearance of the toy member 100 on the 2 nd surface side when the finger structure is bent to the 2 nd state.

As described above, the fitting 108 is connected to the fitting 109 so as to be rotatable with respect to the fitting 109, and fig. 3 (B) shows a case where the fitting 108 is rotated toward the 1 st surface side with respect to the fitting 109. At this time, as shown in fig. 3 (a), the index finger portion 102, the middle finger portion 103, the ring finger portion 104, and the pinky finger portion 105 are bent toward the 1 st surface. Then, the thumb part 101 is rotated in the direction of

arrows

201 and 202, whereby the thumb part 101 is disposed in a horizontal shape below the bent index finger part 102, middle finger part 103, ring finger part 104, and pinky finger part 105.

Next, the structure of each component constituting the toy member 100 will be described with reference to fig. 4 and 5. Fig. 4 is a view showing an example of the exploded structure seen from the 1 st surface side of the hand of the toy component 100, and fig. 5 is an exploded view seen from the 2 nd surface side of the toy component 100.

In fig. 4 and 5, the thumb 101, the index finger 102, the middle finger 103, the ring finger 104, and the little finger 105 are provided with

coupling portions

101a, 102a, 103a, 104a, and 105a, respectively, and the spherical coupling portion of the coupling portion 101a is rotatably connected to a recess 107a provided in the metal fitting 107 in the form of a ball joint. Spherical connecting portions provided at respective end portions of the connecting

portions

102a, 103a, 104a, 105a are rotatably connected to the concave portions 106a to 106d provided in the metal fitting 106 by ball joints.

The metal fitting 106 has

projections

106e and 106f on the lower side, and is rotatably connected to

recesses

107c and 107d of the metal fitting 107. By this connection, the fitting 106 can rotate toward the 1 st surface side with respect to the fitting 107. The fitting 107 has

protrusions

107e, 107f and a recess 107g for connection with the fitting 109, the

protrusions

107e, 107f engaging with the

openings

109c, 109d of the fitting 109, the recess 107g engaging with the protrusion 109e of the fitting 109, thereby ensuring the connection between the fitting 107 and the fitting 109. Further, a projection 107b is provided on the lower side of the metal fitting 107 to be rotatably coupled to the opening 111a of the coupling portion 111.

The fitting 108 includes

protrusions

108a and 108b on the lower side, and the protrusions are rotatably connected to

recesses

109a and 109b provided on the upper side of the fitting 109. By this connection, the metal fitting 108 can be rotated toward the 1 st surface side with respect to the metal fitting 109.

Next, a cross-sectional structure of the toy member 100 in the state 1 in which the hand is opened will be described with reference to fig. 6. Fig. 6 isbase:Sub>A cross-sectional view showing an example ofbase:Sub>A cross-sectional structure of the toy component 100 at the linebase:Sub>A-base:Sub>A ', the line B-B ', the line C-C ', the line D-D ', and the line E-E ' in fig. 2 (base:Sub>A).

Fig. 6 (base:Sub>A) shows an example ofbase:Sub>A cross-sectional configuration of the toy component 100 at the linebase:Sub>A-base:Sub>A', particularlybase:Sub>A cross-sectional configuration of the thumb 101. The thumb part 101 includes a 1 st thumb piece 101b, a 2 nd thumb piece 101c, and a 3 rd thumb piece 101d, and the 2 nd thumb piece 101c is provided with an opening for coupling with the connecting shaft of the 1 st thumb piece 101b and the connecting shaft of the 3 rd thumb piece 101d, respectively. The 1 st thumb piece 101b can be rotated in the direction of arrow 601a with respect to the 2 nd thumb piece 101c via the connecting shaft. In addition, the 2 nd thumb piece 101c is rotatable in the direction of the arrow 601b with respect to the 3 rd thumb piece 101d via the connecting shaft. The 3 rd thumb piece 101d is provided with a coupling portion 101a. The coupling portion 101a has a cross-shaped cross-sectional structure and is configured to be rotatable in the direction of arrow 201 about a cross-shaped vertical axis as a rotation axis.

Fig. 6 (B) shows an example of the cross-sectional configuration of the toy component 100 at line B-B', in particular, the cross-sectional configuration of the forefinger portion 102. The index finger part 102 includes a 1 st index finger part 102b, a 2 nd index finger part 102c, and a 3 rd index finger part 102d, and the 2 nd index finger part 102c is provided with an opening for coupling with the coupling shafts of the 1 st index finger part 102b and the 3 rd index finger part 102d, respectively. The 1 st finger fitting 102b can be rotated in the direction of arrow 602a relative to the 2 nd finger fitting 102c by means of the connecting shaft.

In addition, the 2 nd finger fitting 102c can be rotated in the direction of the arrow 602b with respect to the 3 rd finger fitting 102d via the connecting shaft. The lower end of the 3 rd index finger piece 102d is connected to the coupling portion 102a so as to be rotatable in the direction of the arrow 602 c. An opening for rotatably connecting the 3 rd index finger attachment 102d in the direction of the arrow 602c is provided at the upper end of the coupling portion 102 a. The lower end portion on one side of the coupling portion 102a has a spherical shape, and is connected to the concave portion 106a of the metal fitting 106 in a ball joint manner so as to be rotatable in an arbitrary direction. The metal fitting 107 has a recess 107a, and is connected to the connection portion 101a of the thumb 101 in a ball joint manner so as to be rotatable in the direction of the arrow 202. In the 1 st state shown in fig. 6 (B), the upper surface of the metal fitting 107 is in contact with the flat portion of the bottom surface of the metal fitting 106, but is not in contact with the inclined portion 106g of the bottom surface of the metal fitting 106.

Fig. 6 (C) shows an example of the cross-sectional configuration of the toy component 100 at the line C-C', in particular, the cross-sectional configuration of the middle finger 103. The middle finger part 103 includes a 1 st finger 103b, a 2 nd finger 103c, and a 3 rd finger 103d, and the 2 nd finger 103c is provided with an opening for coupling with the coupling shaft of the 1 st finger 103b and the coupling shaft of the 3 rd finger 103d, respectively. The 1 st finger element 103b can be rotated relative to the 2 nd finger element 103c by means of the connecting shaft in the direction of the arrow 603 a. In addition, the 2 nd pointing element 103c is rotatable with respect to the 3 rd pointing element 103d in the direction of the arrow 603b via the connecting shaft.

The lower end of the 3 rd finger fitting 103d is connected to the connection portion 103a so as to be rotatable in the direction of the arrow 603 c. An opening for rotatably connecting the 3 rd pointing member 103d in the direction of an arrow 603c is provided at an upper end of the connection portion 103 a. The lower end portion of one side of the connection portion 103a has a spherical shape, and is connected to the concave portion 106b of the metal fitting 106 in a ball joint manner so as to be rotatable in an arbitrary direction.

The metal fitting 107 has a recess 107c, and is rotatably connected to the projection 106e of the metal fitting 106, so that the metal fitting 106 can rotate toward the 1 st surface side. Further, the projection 108a of the metal fitting 108 is rotatably connected to the recess 109a of the metal fitting 109, so that the metal fitting 108 can be rotated toward the 1 st surface side. In the 1 st state shown in fig. 6 (C), the inclined portion 107g of the upper surface of the fitting 107 does not contact the bottom surface of the fitting 106, and the flat portion of the upper surface of the fitting 107 contacts the bottom surface of the fitting 106. The projection 107b of the accessory is coupled to the opening 111a of the coupling portion 111, so that the upper side of the toy member 100 with respect to the coupling portion 111 can be rotated in the direction indicated by the arrow 610 with respect to the coupling portion 111.

Fig. 6 (D) shows an example of the cross-sectional structure of the toy component 100 at line D-D', in particular, the cross-sectional structure of the ring finger 104. The ring finger 104 includes a 1 st ring finger 104b, a 2 nd ring finger 104c, and a 3 rd ring finger 104d, and the 2 nd ring finger 104c is provided with an opening for coupling with the connection shaft of the 1 st ring finger 104b and the connection shaft of the 3 rd ring finger 104d, respectively. The 1 st ring finger 104b can rotate relative to the 2 nd ring finger 104c in the direction of the arrow 604a by the connecting shaft. In addition, the 2 nd ring finger fitting 104c is rotatable relative to the 3 rd ring finger fitting 104d in the direction of the arrow 604b via the connecting shaft. The lower end of the 3 rd ring finger 104d is connected to the coupling portion 104a so as to be rotatable in the direction of the arrow 604 c. An opening for connecting the 3 rd ring finger 104d to be rotatable in the direction of arrow 604c is provided at the upper end of the connection portion 104 a. The lower end portion on one side of the coupling portion 104a has a spherical shape, and is connected to the concave portion 106c of the metal fitting 106 in a ball joint manner so as to be rotatable in an arbitrary direction.

The metal fitting 107 has a recess 107d, and is rotatably connected to the projection 106f of the metal fitting 106, so that the metal fitting 106 can rotate toward the 1 st surface side. Further, the projection 108b of the metal fitting 108 is rotatably connected to the recess 109b of the metal fitting 109, so that the metal fitting 108 can be rotated toward the 1 st surface side. In the 1 st state shown in fig. 6 (D), the upper surface of the fitting 107 is in contact with the flat portion of the bottom surface of the fitting 106, but is not in contact with the inclined portion of the bottom surface of the fitting 106. The projection 107b of the metal fitting is coupled to the opening 111a of the coupling portion 111.

Fig. 6 (E) shows an example of the cross-sectional structure of the toy component 100 at the line E-E', in particular, the cross-sectional structure of the small finger 105. The thumb part 105 includes a 1 st thumb part 105b, a 2 nd thumb part 105c, and a 3 rd thumb part 105d, and the 2 nd thumb part 105c is provided with an opening for coupling with the connecting shaft of the 1 st thumb part 105b and the connecting shaft of the 3 rd thumb part 105d, respectively. The 1 st thumb fitting 105b can rotate relative to the 2 nd thumb fitting 105c in the direction of arrow 605a via the connecting shaft. In addition, the 2 nd thumb fitting 105c can be rotated in the direction of the arrow 605b with respect to the 3 rd thumb fitting 105d via the connecting shaft. Further, the lower end portion of the 3 rd thumb piece 105d is connected to the connection portion 105a so as to be rotatable in the direction of the arrow 605 c. An opening for rotatably connecting the 3 rd thumb piece 105d in the direction of arrow 605c is provided at the upper end of the connecting portion 105 a. The lower end portion on one side of the connecting portion 105a has a spherical shape, and is connected to the concave portion 106d of the metal fitting 106 in a ball joint manner so as to be rotatable in an arbitrary direction. In the 1 st state shown in fig. 6 (E), the upper surface of the metal fitting 107 is in contact with the flat portion of the bottom surface of the metal fitting 106, but is not in contact with the inclined portion 106h of the bottom surface of the metal fitting 106.

Next, a cross-sectional structure of the toy component 100 in the 2 nd state where the hand is gripped (closed) will be described with reference to fig. 7. Fig. 7 is a cross-sectional view showing an example of the cross-sectional structure of the toy component 100 at the lines F-F ', G-G ', H-H ', I-I ', and J-J ' in fig. 3.

Fig. 7 (a) shows an example of a cross-sectional structure at the line F-F' of fig. 3, particularly a cross-sectional structure of the thumb 101. Here, the thumb 101 is positioned on the front side (1 st surface side) of the fitting 107 by the rotation of the coupling portion 101a by a predetermined angle with respect to the recess 107a and the rotation of the 3 rd thumb fitting 101d by a predetermined angle with respect to the coupling portion 101a. At this time, the 1 st and 2

nd thumb pieces

101b and 101c may also be rotated appropriately. As is clear from fig. 7 (a), the connection portion 101a is connected to the recess 107a, and the connection portion 101a is locked to the end of the metal fitting 109. In fig. 7 (a), the corner of the part of the fitting 107 protruding toward the 1 st surface side is removed so as not to interfere with the rotation of the 3 rd thumb fitting 101d and the like. The other structure is as described above.

Next, fig. 7 (B) shows an example of a cross-sectional structure at the line G-G' of fig. 3, particularly a cross-sectional structure of the forefinger portion 102. In fig. 7 (B), the 1 st finger fitting 102B is rotated by a 1 st prescribed angle (e.g., about 90 degrees) with respect to the 2 nd finger fitting 102c, the 2 nd finger fitting 102c is rotated by a 2 nd prescribed angle (e.g., about 90 degrees) with respect to the 3 rd finger fitting 102d, and the 3 rd finger fitting 102d is also rotated by a 3 rd prescribed angle (e.g., about 90 degrees) with respect to the fitting 102 a. Thereby, the 1 st finger fitting 102b reaches a position of contact with the surface of the fitting 106. At this time, the thumb 101 is rotated downward by the connection between the 3 rd thumb piece 101d and the connecting portion 101a, thereby avoiding contact with the index finger portion 102. In fig. 7 (B), the metal fitting 106 is tilted forward, and the contact state between the metal fitting 106 and the metal fitting 107 is changed from a state in which the flat portion of the bottom surface of the metal fitting 106 and the upper surface of the metal fitting 107 contact each other as shown in fig. 6 (B) to a state in which the inclined portion 106g of the bottom surface of the metal fitting 106 and the upper surface of the metal fitting 107 contact each other. The fitting 106 has a structure in which the inclined portion 106g is provided in a part of the bottom surface, so that the fitting is easily inclined forward toward the 1 st surface side. The contact state between the metal fitting 108 and the metal fitting 109 is also changed from a state in which the bottom surface of the metal fitting 108 is in contact with the upper surface of the metal fitting 109 shown in fig. 6 (B) to a state in which the bottom surface of the metal fitting 108 is separated from the upper surface of the metal fitting 109.

Next, fig. 7 (C) shows an example of a cross-sectional structure at the line H-H' of fig. 3, particularly a cross-sectional structure of the middle finger portion 103. In fig. 7C, the 1 st finger 103b is rotated by a 1 st predetermined angle (for example, about 90 degrees) with respect to the 2 nd finger 103C, the 2 nd finger 103C is rotated by a 2 nd predetermined angle (for example, about 90 degrees) with respect to the 3 rd finger 103d, and the 3 rd finger 103d is also rotated by a 3 rd predetermined angle (for example, about 90 degrees) with respect to the finger 103 a. Thereby, the 1 st finger fitting 103b reaches a position of contact with the surfaces of the

fittings

106 and 107. In fig. 7 (C), the fitting 106 is tilted forward, and the contact state between the fitting 106 and the fitting 107 is changed from a state in which the bottom surface of the fitting 106 is in contact with the flat portion of the upper surface of the fitting 107 to a state in which the bottom surface of the fitting 106 is in contact with the inclined portion 107g of the upper surface of the fitting 107, as shown in fig. 6 (C). The fitting 107 has a structure in which the fitting 106 is easily tilted forward toward the 1 st surface side by providing an inclined portion 107g in a part of the upper surface. Further, the contact state between the metal fitting 108 and the metal fitting 109 is also changed from a state in which the bottom surface of the metal fitting 108 is in contact with the upper surface of the metal fitting 109 shown in fig. 6 (C) to a state in which the bottom surface of the metal fitting 108 is separated from the upper surface of the metal fitting 109.

Next, fig. 7 (D) shows an example of a cross-sectional structure at the line I-I' of fig. 3, particularly a cross-sectional structure of the ring finger 104. In fig. 7 (D), the 1 st ring finger 104b is rotated by a 1 st prescribed angle (e.g., about 90 degrees) with respect to the 2 nd ring finger 104c, the 2 nd ring finger 104c is rotated by a 2 nd prescribed angle (e.g., about 90 degrees) with respect to the 3 rd ring finger 104D, and the 3 rd ring finger 104D is also rotated by a 3 rd prescribed angle (e.g., about 90 degrees) with respect to the fitting 104 a. Thereby, the 1 st ring finger fitting 104b reaches a position of contact with the surfaces of the fitting 106 and the fitting 107. In fig. 7 (D), the fitting 106 is tilted forward, and the contact state between the fitting 106 and the fitting 107 changes from the state shown in fig. 6 (D) in which the flat portion of the bottom surface of the fitting 106 is in contact with the flat portion of the upper surface of the fitting 107 to the state in which the inclined portion of the bottom surface of the fitting 106 is separated from the inclined portion 107g of the upper surface of the fitting 107. Here, the inclined portions do not contact each other, but may contact each other. The fitting 107 has a structure in which the fitting 106 is easily tilted forward toward the palm side by providing an inclined portion 107g in a part of the upper surface. In addition, the fitting 106 itself has a structure in which the fitting 106 is easily tilted forward toward the palm side by providing a tilted portion and a step in a part of the bottom surface. The contact state between the metal fitting 108 and the metal fitting 109 is also changed from a state in which the bottom surface of the metal fitting 108 is in contact with the upper surface of the metal fitting 109, as shown in fig. 6 (D), to a state in which the bottom surface of the metal fitting 108 is separated from the upper surface of the metal fitting 109.

Next, fig. 7 (E) shows an example of a cross-sectional structure at the line J-J' of fig. 3, particularly a cross-sectional structure of the little finger portion 105. In fig. 7 (E), the 1 st thumb fitting 105b is rotated by a 1 st prescribed angle (e.g., about 90 degrees) with respect to the 2 nd thumb fitting 105c, the 2 nd thumb fitting 105c is rotated by a 2 nd prescribed angle (e.g., about 90 degrees) with respect to the 3 rd thumb fitting 105d, and the 3 rd thumb fitting 105d is also rotated by a 3 rd prescribed angle (e.g., about 90 degrees) with respect to the fitting 105 a. Thereby, the 1 st thumb fitting 105b reaches a position of contact with the surface of the fitting 106. In fig. 7 (E), the fitting 106 is tilted forward, and the contact state between the fitting 106 and the fitting 107 changes from the state shown in fig. 6 (E) in which the flat portion of the bottom surface of the fitting 106 is in contact with the upper surface of the fitting 107 to the state in which the flat portion of the bottom surface of the fitting 106 is separated from the upper surface of the fitting 107 and is tilted toward the tilted portion 106h side of the bottom surface of the fitting 106. The fitting 106 has a structure in which the fitting 106 is easily inclined toward the 1 st surface side by providing the inclined portion 106h in a part of the bottom surface. The contact state between the metal fitting 108 and the metal fitting 109 is also changed from a state in which the bottom surface of the metal fitting 108 is in contact with the upper surface of the metal fitting 109 shown in fig. 6 (E) to a state in which the bottom surface of the metal fitting 108 is separated from the upper surface of the metal fitting 109.

In the explanation of fig. 7, the rotation angles of the respective attachments from the index finger portion 102 to the thumb portion 105 are commonly set to the 1 st predetermined angle, the 2 nd predetermined angle, and the 3 rd predetermined angle, but this is for the sake of simplifying the explanation, and there is no intention to prohibit the rotation angles from being different from each other, and the case of performing the rotation at the different angles is included in the scope of the embodiment.

In the above description of the embodiment, the metal fitting 108 is configured to rotate independently of the metal fitting 106, but an engagement member that engages with the metal fitting 106 may be added to the metal fitting 108, so that the metal fitting 108 can rotate in conjunction with the operation of the metal fitting 106.

According to the present embodiment, a toy component of a hand for assembling a toy can be provided. In this toy member, when the hand grips, the root portions of the 5 fingers are also turned toward the palm side, and therefore, the grip performance can be improved. Further, the

fittings

108 and 109 can reduce unnatural and unnatural appearance when the hand grips the fitting.

The present invention is not limited to the above-described embodiments, and various modifications and changes can be made within the scope of the present invention.

Claims

1. A toy part which is a toy part of a hand of a model toy, wherein,

the toy component comprises:

a plurality of 1 st finger structures each configured to be bendable toward the 1 st surface of the toy member;

a 1 st member to which the 1 st finger structures are rotatably connected;

a 2 nd member, the 1 st member being rotatably connected to the 2 nd member;

a 1 st cover member coupled to a 2 nd surface side of the 2 nd member opposite to the 1 st surface; and

a 2 nd cover member rotatably connected to the 1 st cover member,

the toy components of the hand have a 1 st state with the hand open and a 2 nd state with the hand closed,

in the 2 nd state, the 1 st member and the 2 nd cover member are configured to be rotatable toward the 1 st surface side in accordance with the bending of the plurality of 1 st finger structures toward the 1 st surface side.

2. The toy component of claim 1,

each of the 1 st finger structures has a 1 st connecting part having a spherical end part,

the 1 st member has a plurality of 1 st recesses, the plurality of 1 st recesses being provided on a surface of the 1 st member and corresponding to the 1 st coupling parts of the plurality of 1 st finger structures,

the 1 st finger structures are rotatably connected to the 1 st member by coupling the 1 st coupling portions to the 1 st recesses.

3. The toy component of claim 2,

the 1 st member has the plurality of 1 st recesses at different heights.

4. The toy component of claim 2 or 3,

each of the 1 st finger structures includes:

1 st part;

a 2 nd fitting rotatably connected to the 1 st fitting;

a 3 rd fitting rotatably connected to the 2 nd fitting; and

a 4 th fitting which is rotatably connected to the 3 rd fitting and has the 1 st coupling portion,

the toy part of the hand transitions to the 2 nd state by performing the following actions in the 1 st state:

the 1 st fitting is rotated by a 1 st prescribed angle relative to the 2 nd fitting;

the 2 nd fitting is rotated by a 2 nd prescribed angle relative to the 3 rd fitting; and

the 3 rd fitting is rotated by a 3 rd prescribed angle with respect to the 4 th fitting.

5. A toy part according to any one of claims 1-4,

the 1 st member includes a 1 st flat portion and a 1 st inclined portion at least in part of a bottom surface,

in the 1 st state, the 1 st member is in contact with the upper surface of the 2 nd member by the 1 st flat portion,

in the 2 nd state, the 1 st member is in contact with the upper surface of the 2 nd member with the 1 st inclined portion.

6. A toy part according to any one of claims 1-5,

the upper surface of the 2 nd component at least partially comprises a 2 nd flat part and a 2 nd inclined part,

in the 1 st state, the 2 nd member is in contact with the bottom surface of the 1 st member by the 2 nd flat part,

in the 2 nd state, the 2 nd member contacts the bottom surface of the 1 st member with the 2 nd inclined portion.

7. The toy component of any one of claims 1-6,

the 1 st cover member is configured to cover at least a part of a side surface of the 2 nd member and the 2 nd surface side,

the 2 nd cover member is configured to cover at least a part of a side surface of the 1 st member and the 2 nd surface side.

8. The toy component of any one of claims 1-7,

the toy member further includes a 2 nd finger structure, the 2 nd finger structure being configured to be bendable toward the 1 st surface of the toy member,

the 2 nd finger structure is rotatably connected to the 2 nd member,

the 2 nd finger structure is configured to be bent in a direction intersecting a bending direction of the 1 st finger structures in the 2 nd state.

9. The toy component of claim 8,

the 2 nd finger structure has a 2 nd coupling part having a spherical end part,

the 2 nd member has a 2 nd recessed portion provided on a surface of the 2 nd member, the 2 nd recessed portion corresponding to the 2 nd coupling portion of the 2 nd finger structure,

the 2 nd finger structure is rotatably connected to the 2 nd member by coupling the 2 nd coupling portion and the 2 nd concave portion.

10. The toy component of claim 9,

the 2 nd finger structure includes:

a 5 th fitting;

a 6 th fitting rotatably connected to the 5 th fitting;

a 7 th fitting rotatably connected to the 6 th fitting; and

an 8 th fitting rotatably connected to the 7 th fitting and having the 2 nd coupling portion,

the toy part of the hand transitions to the 2 nd state by at least the following actions in the 1 st state:

the 8 th fitting is rotated by a 4 th prescribed angle relative to the 2 nd member; and

the 7 th fitting is rotated by a 5 th predetermined angle with respect to the 8 th fitting.

11. The toy component of any one of claims 1-10,

the 2 nd member is also rotatably coupled to a member constituting a wrist of the model toy.

12. A model toy, wherein,

the model toy has a toy component according to any one of claims 1 to 11.