阅读说明：本技术 一种圆珠游戏装置 (Ball game device ) 是由 原永坚 于 2021-10-31 设计创作，主要内容包括：本发明涉及一种益智玩具,尤其指一种圆珠类玩具。它包含盒体和圆珠,盒体由底板、盒盖与围边组成,圆珠置于盒体容腔内。底板上有通孔阵列,通孔阵列内的通孔贯穿底板,圆珠可嵌入通孔,圆珠上有标识符号,便于分组或排序。手指从盒底的通孔干预圆珠,手腕摆动盒体可移动圆珠,然后实现对圆珠分组或者排序。本文所描述的圆珠游戏装置可用于训练平衡感知能力和逻辑思维能力。为人们提供了一种消遣、解压或者竞技用的游戏道具,丰富了圆珠游戏的玩法。(The invention relates to an intelligence toy, in particular to a ball toy. The novel box comprises a box body and beads, wherein the box body is composed of a bottom plate, a box cover and a surrounding edge, and the beads are arranged in a containing cavity of the box body. The bottom plate is provided with a through hole array, through holes in the through hole array penetrate through the bottom plate, the round beads can be embedded into the through holes, and the round beads are provided with identification symbols, so that grouping or sorting is facilitated. The fingers intervene the round beads from the through holes at the bottom of the box, the wrist swings the box body to move the round beads, and then the round beads are grouped or sorted. The ball game device described herein may be used to train balance perception capabilities and logical thinking capabilities. Provides a game prop for recreation, decompression or competition for people and enriches the playing method of the ball game.)

1. The utility model provides a ball game device, contains box body and ball, the box body comprises bottom plate, lid and surrounding edge, the ball is arranged in the intracavity is held to the box body, its characterized in that: the device comprises a through hole array which is arranged on the bottom plate; through holes in the through hole array penetrate through the bottom plate; the round beads can be embedded into the through holes and can be arranged in the through hole array; the beads have distinguishable groups or sequences of identifying symbols.

2. The ball game apparatus according to claim 1, wherein: the through hole is a round hole; the diameter of the round hole is smaller than that of the round ball; the hole center distance of the adjacent round holes is not less than the diameter of the round bead.

3. The ball game apparatus according to claim 1, wherein: the identification symbol is any one or combination of several of color, number, character symbol and figure; the identification symbol is attached to the surface of the bead body or is embedded into the light-transmitting bead body.

4. The ball game apparatus according to claim 1, wherein: the upper surface of the bottom plate is one of a plane, a wavy curved surface or a rotating curved surface; the wave curved surface takes the shortest path between the adjacent through holes as the wave trough of the curved surface, and takes the position far away from the wave trough and the through holes as the wave crest of the curved surface.

5. The ball game apparatus according to any one of claims 1 to 4, wherein: the through hole array is a through hole matrix which is a set of through holes with rows and columns approximately vertically intersected and integrally distributed in a rectangular shape; the through hole matrix at least comprises three rows and three columns of the through holes.

6. The ball game apparatus according to claim 5, wherein: the total number of the round beads is one less than that of the through holes, and the round beads and the rest of the through holes can be matched in a one-to-one correspondence manner; the balls are grouped according to the rows of the through hole matrix, one row of the balls is a group, the balls in the same group are consistent in color, and the balls in different groups are different in color.

7. The ball game apparatus according to claim 6, wherein: the number of rows and the number of columns of the through hole matrix are the same; the beads are marked with numbers or letters as sequence identification symbols, the beads in the same row are marked with the sequence identification symbols in sequence, and the beads in the same row have the same sequence identification symbols.

8. The ball game apparatus according to any one of claims 1 to 4, wherein: the array of vias comprises a set of seven-hole annular arrays; the seven-hole annular array consists of a central through hole and a six-hole through hole ring; the six-hole through hole ring is a set of six through holes and is annularly distributed around the central through hole.

9. The ball game apparatus according to claim 8, wherein: the through hole array comprises a thirty-seven hole annular array, and the thirty-seven hole annular array consists of the seven hole annular array, a twelve hole through hole ring and an eighteen hole through hole ring; the through holes in the thirty-seven-hole annular array are uniformly distributed around the central through hole and are hexagonal as a whole; the distance between the adjacent through holes is basically equal; the twelve-hole through hole ring is a set of twelve through holes and is distributed around the seven-hole annular array in a hexagon manner; eighteen through-hole rings are the collection of eighteen through-holes, surround twelve through-hole rings are the hexagon equipartition.

10. The ball game apparatus according to claim 9, wherein: the thirty-seven aperture annular array matches thirty-six of the beads; the round beads are divided into six groups, and each group of the round beads comprises six round beads; the same group of the beads have the same color, and the different groups of the beads have different colors.

Technical Field

The invention relates to an intelligence toy, in particular to a ball toy.

Background

The ball balance game toy is a toy for experiencing balance, the game process shows the ability of participants to sense and master the balance state of the balls, and the toy mainly comprises a box body and the balls arranged in a containing cavity of the box body. The box body consists of a bottom plate, a box cover and a surrounding edge. The surrounding edge can be an upturned edge of the bottom plate, a sagging edge of the cover, or a part which has a blocking function independently, and aims to limit the moving range of the ball and prevent the ball from falling. The lid is generally transparent, the beads being visible; the ball is restrained in the box body and can roll on the upper surface of the bottom plate. Typically, the base plate is provided with dimples, and the play participants swing the case to let the ball enter the dimples for the play task. And a path is arranged between the bottom plate and the panel of some toys, a pit is arranged on the path, the ball rolls along the path, and if the ball avoids the pit and reaches a designated position, the game task is completed. Generally, the displacement of the ball is controlled by swinging the box body, and a player with good balance can smoothly complete a task. As is common, the floor structure is closed: one structure is that the pit is a blind hole and is arranged on the bottom plate; the other structure is that the through hole is arranged on a separation plate, the separation plate is arranged between a bottom plate and a cover plate, and the bottom plate is also closed. Without opening the cover, the ball cannot be reached by the player, and the movement of the ball cannot be accurately intervened, for example, it is difficult to transfer a ball that has fallen into one pocket to another pocket. On the other hand, the arrangement of the pits or hole sites is irregular, and certain game rules with strong logic are difficult to define. Therefore, the ball balance game toy in the prior art is suitable for experiencing balance feeling, and is difficult to be used for experiencing intelligence development activities with strong logic, such as ball classification and sorting.

The patent document entitled "a palmtop maze toy" entitled with CN206463485U, which shows a part of the above structural features, can be used for experiencing a sense of balance, and is not suitable for experiencing a sorted or ordered game.

In summary, the main drawbacks of the ball balance game toy of the prior art are: under the lid closed condition, the ball of box body appearance intracavity can't accurately shift, and the pit or the hole site overall arrangement of ball are mixed and disorderly, are difficult to further carry out the grouping or the sequencing activity that the logicality is stronger.

Disclosure of Invention

The invention aims to provide a game device which can manually intervene in the balance state and position of a ball to realize the classification or sequencing of the ball.

In order to achieve the purpose, the invention provides a ball game device, which comprises a box body and balls, wherein the box body consists of a bottom plate, a box cover and a surrounding edge, and the balls are arranged in a containing cavity of the box body; the ball game device comprises a through hole array, wherein the through hole array is arranged on a bottom plate; the through holes in the through hole array penetrate through the bottom plate; the round beads can be embedded into the through holes and can be arranged in the through hole array; the beads have identifying symbols that can be grouped or sequenced.

Preferably, the through hole is a round hole; the diameter of the round hole is smaller than that of the round ball; the hole center distance between the adjacent round holes is not less than the diameter of the round ball.

Preferably, the identification symbol is any one of color, number, character symbol and figure or their combination; the identification symbol is attached to the surface of the bead body or embedded in the light-transmitting bead body.

Optionally, the upper surface of the bottom plate is one of a plane, a wavy curved surface, or a rotating curved surface; the wave curved surface takes the shortest path between the adjacent through holes as the wave trough of the curved surface, and takes the position far away from the wave trough and the through holes as the wave crest of the curved surface.

Preferably, the through hole array is a through hole matrix, and the through hole matrix is a set of through holes with rows and columns approximately vertically intersected and integrally distributed in a rectangular shape; the through hole matrix at least comprises three rows and three columns of through holes.

Furthermore, the total number of the round beads is one less than that of the through holes, and the round beads and the rest of the through holes can be matched in a one-to-one correspondence manner; the balls are grouped according to the rows of the through hole matrix, the balls in one row form one group, the balls in the same group have the same color, and the balls in different groups have different colors.

Furthermore, the number of rows and the number of columns of the through hole matrix are the same; the beads are marked with numbers or letters as sequence identification symbols, the beads in the same row are marked with the sequence identification symbols in sequence, and the beads in the same row have the same sequence identification symbols.

Preferably, the array of vias comprises a set of seven-hole annular arrays; the seven-hole annular array consists of a central through hole and a six-hole through hole ring; the six-hole through hole ring is a set of six through holes and is annularly distributed around the central through hole.

Furthermore, the through hole array comprises a thirty-seven hole annular array, and the thirty-seven hole annular array consists of a seven hole annular array, a twelve hole through hole ring and an eighteen hole through hole ring; through holes in the thirty-seven hole annular array are uniformly distributed around the central through hole, and the whole body is hexagonal; the distance between the adjacent through holes is basically equal; the twelve-hole through hole ring is a set of twelve through holes and is hexagonally and uniformly distributed around the seven-hole annular array; the eighteen-hole through hole ring is a set of eighteen through holes and is distributed around the twelve-hole through hole ring in a hexagonal manner.

Further, thirty-seven hole annular arrays are matched with thirty-six round beads; the round beads are divided into six groups, and each group of round beads is six; the same group of beads have the same color, and different groups of beads have different colors.

The invention has the beneficial effects that: the ball game device described herein may be used to train balance perception capabilities and logical thinking capabilities. On the one hand, in the hand balance feeling experience process, the finger touch feeling, the wrist flexibility and the hand-eye coordination are exercised. The ball game device is held by a game participant, fingers can touch the bottom of the ball through the through hole, and the wrist swings the box body to control the rolling direction of the ball, so that the ball is moved to a target position. In this process, the eyes, fingers and wrists are required to coordinate to grasp balance. On the other hand, logical thinking ability, i.e., ability to exercise categories or orders, may be exercised. In the whole game process, the beads are changed from a disordered state to an ordered state. The participants need to carefully think and clear the position relation between the round beads to select the correct displacement path, and complete the grouping or sequencing by fewer steps. In summary, the ball game device described herein can be used to train balance perception and logical thinking capabilities. Provides a game prop for recreation, decompression or competition for people and enriches the playing method of the ball game.

Drawings

FIG. 1 is a perspective view of a matrix-type embodiment of a ball game device.

FIG. 2 is a top view of a matrix-type embodiment of a base plate and ball assembly of a ball game device.

Fig. 3 is a perspective view of an annular array type embodiment of the ball game device.

FIG. 4 is a top view of an annular array of the base plate and ball combination of the ball game device.

FIG. 5 is a plan view of a rotating curved surface type embodiment of the ball game device.

Fig. 6 is a schematic sectional view taken along line a-a of fig. 5.

Reference numerals: 1-box body, 2-ball, 3-surrounding edge, 11-bottom plate, 12-box cover, 110-through hole, 111-bottom plate surrounding edge, 121-box cover surrounding edge, 112-groove, mn-through hole matrix, m 1-first row of through holes, m 2-second row of through holes, m 3-third row of through holes, m 4-fourth row of through holes, m 5-fifth row of through holes, m 6-sixth row of through holes, n 1-first column of through holes, n 2-second column of through holes, n 3-third column of through holes, n 4-fourth column of through holes, n 5-fifth column of through holes, n 6-sixth column of through holes, o-center through hole, c 6-six-hole ring, c 12-twelve-hole ring, c 18-eighteen-hole ring, x-first symmetry axis, y-second symmetry axis, z-third axis of symmetry, R-axis of rotation.

Detailed Description

The following detailed description of embodiments of the invention refers to the accompanying drawings.

In the description herein, a via array refers to a collection of regularly arranged vias; the through hole matrix is a set of through holes with rows and columns approximately vertically intersected and integrally distributed in a rectangular shape; the annular array is a set of through holes which surround the center and are distributed in an annular expansion manner; the through hole ring refers to a collection of through holes distributed in a ring shape. FIGS. 1 and 2 illustrate the same matrix-type embodiment, referred to as the first embodiment; FIGS. 3 and 4 illustrate the same annular array type embodiment, referred to as the second embodiment; fig. 5 and 6 illustrate the same circular array type embodiment with rotating surface features, referred to as a third embodiment. In the first embodiment, "rows" and "columns" are a collection of through holes distributed along a straight line, the rows being substantially parallel to each other, the columns being substantially parallel to each other, the row and column directions being substantially perpendicular to each other, the intersection of the rows and columns being the location of the through holes. For convenience of description, in the first embodiment, the corresponding through holes are represented by a combination of row and column reference numerals of a through hole matrix, such as: m1n1 represents the through-hole where the first row meets the first column, and also represents the coordinates of the through-hole, which may be referred to as through-hole m1n 1. Vias 110 generally refer to vias within a via array.

Fig. 1 and 2 show a matrix-type embodiment of a ball game device, i.e., a perspective view of a first embodiment of the present disclosure, and fig. 2 is a top view of a base plate and ball assembly of the embodiment of fig. 1.

The ball game device of the first embodiment comprises a box body 1 and balls 2, wherein the box body 1 consists of a bottom plate 11, a box cover 12 and surrounding edges, the surrounding edges of the box body 1 consist of a drooping box cover surrounding edge 121 and an upturned bottom plate surrounding edge 111, and the balls 2 are arranged in a containing cavity of the box body 1; the game device comprises a through hole array, wherein the through hole array is a through hole matrix mn which is arranged on a bottom plate 11; the through holes 110 in the through hole matrix mn penetrate the bottom plate 11; the ball 2 can be inserted into the through hole 110, specifically: the bottom of the ball 2 can partially fall into the through hole 110, and the through hole 110 can support the ball 2; the beads 2 have identification symbols which can be distinguished in groups or sequences, and the beads 2 can be orderly arranged on the through hole matrix mn according to the identification symbols.

The box body 1 is provided with a containing cavity for containing the ball 2, and the ball 2 can move in the containing cavity; the surrounding edge of the box body 1 plays a role in limiting the moving range of the ball 2 and protecting the ball 2 from falling, and separates the box cover 12 and the box bottom 11 to form a containing cavity. The bottom plate 11, the box cover 12 and the surrounding edges are connected in a matching mode through various common box body and box cover matching modes. The lid 12 of fig. 1 is made of transparent material and is in an open state.

It is generally preferred that the box body is made of plastic, the box body in the first embodiment is made of plastic, and the box cover 12 is made of transparent material; if the box cover 12 is made of non-transparent material, a viewing hole or a window needs to be designed on the box cover, or a game participant needs to open the box cover 12 to observe the state of the ball when operating. The base plate 11 may be made of metal, so that a thinner and stronger base plate can be obtained. The ball 2 can be made of various common materials, such as plastic, glass, metal, etc.

All the through holes 110 in the matrix of through holes mn extend through the bottom plate 11, since the through holes 110 are channels for the fingers to interfere with the ball 2, in addition to supporting and positioning the ball 2. The game participant presses the bottom of the through hole 110 with fingers, especially with the meat pad on the fingertip, the ball 2 on the through hole 110 will be jacked up, the potential energy of the jacked ball 2 will be slightly higher than that of the other balls 2, when the box body 1 is swung, the ball 2 rolls first, the balls 2 on the other through holes 110 are in a static state relative to the bottom plate 11, and the above process shows the displacement mode of the ball 2. While the blind hole does not contribute to interfering with the displacement of the ball 2.

The thickness of the bottom plate 11 determines the depth of the through-hole 110. If the aperture of the through hole 110 is smaller, the thinner the thickness of the bottom plate 11 is, the more convenient the use is, the meat pad on the finger can be used to extrude and touch the bottom of the ball 2 through the through hole 110; if the aperture of the through hole is larger, for example, the aperture is larger than the width of the finger, the thickness of the bottom plate 11 has a little influence on the operation, and even the finger can extend into the through hole to touch the ball 2.

The circular hole is a preferable form of the through hole, and the through hole 110 in the first embodiment is a circular hole. The through holes may have other shapes, such as square, polygon or other irregular patterns, so as to ensure that the through holes 110 can support the ball 2. Each cross-section of the ball 2 is circular, and the through-hole that best matches it is a circular hole. The circular through hole achieves a maximum effective support area with a minimum open area compared to other shapes. Meaning that the same open area, a circular hole, gives the bead 2 the most stable state. The round hole also has the characteristic of convenient processing. Therefore, a circular through hole is a preferred choice for the shape of the through hole.

The effective aperture of the through-hole 110 in the first embodiment, i.e., the diameter of the circular hole, is slightly smaller than the diameter of the ball 2. The effective aperture of a via of other shapes is defined as the diameter of an inscribed or inscribed circle of the cross-section of the via. The size of the effective aperture of the through-hole 110 relative to the size of the ball 2 has an influence on the stable state of the ball 2 on the base plate 11. The larger the effective aperture of the through-hole 110 is, the larger the effective area for supporting the ball 2 is, and the deeper the depth of the ball 2 falling into the through-hole 110 is. The closer the effective pore size is to the bead 2 and the smaller the diameter is than the bead 2, the better the stability of the bead 2. Generally, if the effective pore diameter is larger than the diameter of the ball 2, the through-hole 110 cannot support the ball 2. Designing a through hole with the size similar to that of the ball 2 for the game device which experiences the logic thinking in a biased way according to the size of the matched ball 2; a game device with a small through hole is designed for experiencing balance feeling with emphasis.

The via spacing can also affect the gaming experience. The hole pitch is measured herein as the pitch between the through holes 110. The pitch is a distance between centers of inscribed circles or inscribed circles of the cross section of the through-hole 110. The hole center distance of the adjacent through holes 110 cannot be smaller than the diameter of the matched ball 2. In the first embodiment, as shown in fig. 2, if the distance between the centers of any adjacent through holes 110 in the same row or column is smaller than the diameter of the ball 2, the ball 2 will interfere with each other, which affects the normal arrangement of the ball 2. In the second embodiment, as shown in fig. 4, the hole center distance between any two adjacent through holes 110 is significantly larger than the diameter of the ball 2. In the circular array, the width of the channel where the ball moves is clamped by the balls 2 at the two sides of the channel, which may be smaller than the diameter of the ball, and when the ball 2 moves to the adjacent through hole 110, the ball is interfered by the ball 2 at the two sides of the channel which is stationary. For example, if the distance between the centers of the adjacent through holes 110 on the through hole ring c6 is equal to the diameter of the ball 2, any one ball 2 moving into the central through hole o may be hindered by the ball moving into both sides of the channel, because the width of the channel is smaller than the diameter of the ball in this case. The ball 2 can not move smoothly due to the obstruction, but the ball 2 can not be prevented from moving, after all, the channel formed by clamping the balls at the two sides is still a channel with low potential energy, and the ball 2 can pass through the channel only by being slightly higher than the adjacent ball 2. The larger the hole center distance is, the longer the distance of the ball 2 moving between the through holes is, the uncertainty of the motion track is increased, the motion speed is difficult to control, and the positioning difficulty is increased. By utilizing the characteristic, the game device for training the unbalanced balance sense can be designed with larger hole center distance.

Optionally, the upper surface of the bottom plate 11 is one of a plane, a wavy curved surface, or a rotating curved surface.

The advantage of the upper surface of the base plate 11 being planar is that: the plane is simple, the processing and the manufacturing are convenient, and the probability of the ball 2 moving in any direction of the plane is the same. The first and second embodiments both adopt a planar structure.

The upper surface of the bottom plate 11 may also be designed to be curved.

Further, the upper surface of the base plate 11 may be designed as a wave-shaped curved surface, and the shortest path between any adjacent through holes 110 may be made as a trough of the curved surface. For example, on the basis of the first embodiment, the valleys of the curved surface may be constructed for each row, each column, and the central axis and the vicinity thereof. And the area far away from the wave trough and the through hole can be made into the wave crest of a curved surface, for example, the central position between the through hole m1n1 and the through hole m2n2 and the vicinity thereof can be made into the wave crest of a curved surface. For another example, on the basis of the second embodiment, the connecting line of the centers of any three mutually adjacent through holes 110 in the circular array forms a triangle, the center of the triangle can construct a peak of the curved surface, and the shortest path between any two through holes 110 can construct a trough of the curved surface. Generally, the moving path of the ball 2 is a valley rather than a peak. The wave-shaped curved surface has the advantages that the wave trough has a certain guiding function, so that the possibility of deviation of the ball 2 during movement is reduced; after the box is shaken again to disorder the sequence of the ball 2, the wave crest makes the ball 2 fall back to the through hole 110 more quickly. The principle is that the ball 2 tends to a position with low potential energy under the action of gravity. The wavy curved surface structure is suitable for a game device controlled by the bias weight logic.

The upper surface of the bottom plate 11 may also be designed as a surface of revolution. For example, the bottom surface of the third embodiment has a surface of revolution feature. For details, reference is made to the description below.

The array of through holes on the bottom plate 11 in the first embodiment is a through hole matrix mn, which provides a set of 36 through holes with mutually perpendicular rows and columns, and the through hole matrix mn has six rows and six columns of through holes 110, where m1, m2, m3, m4, m5, and m6 represent the set of through holes in each row, and n1, n2, n3, n4, n5, and n6 represent the set of through holes in each column. The matrix of through holes mn defines the distribution of the sets of beads. Since the number of rows is equal to the number of columns, the via matrix mn may also be referred to as a via matrix. Obviously, the through hole matrix mn includes a three-step through hole matrix, for example, 9 through holes 110, i.e., m1n1, m1n2, m1n3, m2n1, m2n2, m2n3, m3n1, m3n2, and m3n3, are distributed in three rows and three columns to form the three-step through hole matrix. The third order via matrix can be considered as the smallest unit of the via matrix because the number of vias smaller than the third order via matrix is too small to be meaningful for grouping or sorting the beads 110.

The identification symbol (not shown) of the ball 2 is any one of color, number, letter symbol, figure or their combination. The identification symbol is attached to the surface of the bead body, such as painting, imprinting, drawing and other process methods, the identification symbol can be displayed on the surface of the bead body, and the identification symbol can be displayed by modulating the material of the bead body with different colors. The identification symbol can also be implanted into the interior of the bead body, for example, various three-dimensional figure patterns can be implanted into the transparent and semitransparent bead body material. The identification symbol of the first embodiment is formed by combining color and number, the color of the bead body is obtained by modulating the material of the bead body, and the number is printed on the surface of the round bead 2. The colors of the round beads 2 corresponding to m1, m2, m3, m4, m5 and m6 are red, orange, yellow, green, blue and purple in sequence; each row of beads 2 corresponding to n1, n2, n3, n4, n5 and n6 is sequentially marked with numeral symbols 1 to 6. Thus, a ball set 'red 2, red 3, red 4, red 5, red 6' is constructed; orange 1, orange 2, orange 3, orange 4, orange 5, orange 6; yellow 1, yellow 2, yellow 3, yellow 4, yellow 5, yellow 6; green 1, green 2, green 3, green 4, green 5, green 6; blue 1, blue 2, blue 3, blue 4, blue 5, blue 6; violet 1, violet 2, violet 3, violet 4, violet 5, violet 6 ", 35 particles in total, divided into 6 groups. Orderly arranging the round beads 2 into a through hole matrix mn, wherein the round beads 2 in the same group have the same color and are ordered according to the numerical sequence; the sequential identification symbols of the beads in the same column are the same, and the colors are different. The ball 2 at the through hole m1n1 in the first embodiment is not placed, i.e., the ball 2 of "red 1" is not present, and the number of the balls 2 is one less than that of the through holes 110 in order to leave an operation space.

If the ball 2 in the first embodiment is color-differentiated only without a numerical identifier, the ball game apparatus is suitable for a ball grouping game, or a game for sorting balls in color order, a simple logical thinking game and concentration training. If the ball 2 is not color-coded, and has numerical identifiers of 1 to 35, the ball game apparatus is suitable for a numerical sorting game with a large difficulty.

Regarding how the number of the beads is matched with the number of the through holes, three cases are distinguished: the number of the round beads 2 is consistent with that of the through holes 110; the number of the beads 2 is less than that of the through holes 110; the ball 2 has a larger number of through holes 110. How to select is considered in the specific case. The first embodiment and the second embodiment both adopt the scheme that the number of the round beads is one less than that of the through holes, which is a better choice. Because, during the grouping or sorting process, there is at least one empty via 110 for the shifting operation. If the number of the round beads is consistent with that of the through holes, after the round beads 2 of the number 'red 1' are placed, game participants break the sequence of the round beads 2 and take out any one or more round beads 2, and then grouping and sequencing can be started. Which ball to take out is also tested for the judgment ability of the game participants, and a ball favorable for reducing the total number of movements is usually selected to take out. As shown in fig. 5, "the number of beads is as many as the number of through holes" in the third embodiment, there is enough place on the bottom plate 11 to accommodate the beads 2; the interference balls can also be configured on the basis of the third embodiment, and the number of the balls is more than that of the through holes, so that the difficulty of the game can be increased.

Fig. 3 shows a perspective view of a circular array type embodiment of the ball game apparatus, and fig. 4 is a top view of the combination of the base plate 11 and the ball 2 of the embodiment of fig. 3, and the second embodiment will be further described with reference to these figures.

The ball game device of the second embodiment comprises a box body 1 and balls 2, wherein the box body 1 is composed of a bottom plate 11, a box cover 12 and a surrounding edge 3, the balls 2 are arranged in a containing cavity of the box body 1, and the bottom plate of the device is provided with a through hole array which is an annular array. The through holes 110 in the annular array penetrate through the bottom plate 11, and the round beads 2 can be embedded into the through holes 110; the beads 2 have identification symbols that can be grouped or sequenced.

The annular array of the second embodiment is a thirty-seven hole annular array having three through-hole rings and one central through-hole o. The first through-hole ring is uniformly distributed around the central through-hole o and is provided with 6 through-holes 110, namely a six-hole through-hole ring c 6; the six-hole through hole ring c6 and the central through hole o form a seven-hole annular array; the second through hole ring is provided with 12 through holes 110 which are uniformly distributed around the six-hole through hole ring c6 and is called a twelve-hole through hole ring c 12; the third through hole ring is provided with 18 through holes 110 which are uniformly distributed around the twelve through hole rings c12 and are called eighteen through hole rings c 18; the centers of the through holes in the through hole rings are sequentially connected to form a hexagonal structure; the distance between any two adjacent through holes is basically equal. The through hole set with the arrangement rule also has the following characteristics: the top point of the hexagonal through hole ring is provided with a through hole 110; there are three symmetry axes through the vertex and center of the hexagon: the included angle between any two symmetrical axes is 60 degrees; the symmetry axes of the through hole rings are basically overlapped; the through holes 110 on the axis of symmetry are arranged in a linear sequence. The thirty-seven-hole annular array provides a group of through hole sets with definite hole number and ordered arrangement as the support position and the target position of the ball 2, and the ball sets can be distributed orderly by means of the annular array.

Other annular through hole arrays can be expanded based on the seven-hole annular array, such as a nineteen-hole, sixty-one hole, ninety-one hole and other hexagonal annular arrays; or a through hole array with other layout structures including a seven-hole annular array is expanded, such as a through hole array with a symmetrical layout structure like a triangle, a diamond and the like.

The identification symbol (not shown) of the ball 2 in the second embodiment is six different colors attached to the surface of the ball. There are 6 each of red, orange, yellow, green, cyan, blue, for a total of 36, one less than the number of through holes 110 of the thirty-seven hole annular array. After the game participants shake the box, the round beads 2 are rearranged and grouped, the round beads 2 with the same color can be intensively distributed in a triangular shape and uniformly surround the central through hole, and each triangle is identical with six hexagons. Another arrangement that can be implemented is: the round beads 2 are arranged in a circular sequence with 6 circular sections, wherein the round beads are arranged adjacently in the sequence of red, orange, yellow, green, cyan and blue.

The following bead combinations can also be matched using the thirty-seven aperture annular array in the second embodiment: the color round beads 2 are 6: red, orange, yellow, cyan, blue and purple are respectively one, and 15 white round beads 2 and 15 black round beads 2 are respectively provided. After the game participant shakes the box, rearrange the ball 2, can realize finally: the 6 colored balls 2 are arranged in a straight line in sequence and are positioned on one of the symmetry axes, the ball 2 is not arranged at the central through hole o, and the white balls 2 and the black balls 2 are divided into two groups and are positioned at two sides of the colored balls 2. The identification symbols are composed in various ways, and the arranged regularly circulated patterns are also various. To give another simple example: the matched round beads 2 are divided into two groups, namely 18 red round beads and 18 blue round beads, after the box is shaken, the red round beads 2 and the blue round beads 2 can be divided into two groups, and then the game task is finished.

The third embodiment is further described below with reference to fig. 5 and 6.

The ball game device of the third embodiment comprises a box body 1 and balls 2, wherein the box body 1 consists of a bottom plate 11, a box cover 12 and surrounding edges, the surrounding edges of the box body 1 consist of a drooping box cover surrounding edge 121 and an upturned bottom plate surrounding edge 111, and the balls 2 are arranged in a containing cavity of the box body 1; the device comprises a through hole array which is a seven-hole annular array. The seven-hole annular array is arranged on the bottom plate 11; the through hole 110 penetrates through the bottom plate 11, and the ball 2 can be embedded into the through hole 110; the beads 2 have identification symbols that can be grouped or sequenced.

A significant feature of the third embodiment is that the upper surface of the base plate 11 has a rotationally curved surface feature. The rotating curved surface is characterized in that the height of the curved surface can be changed at different positions far away from the rotating shaft R; and the heights of the curved surfaces are consistent at the positions with the same distance from the rotating shaft R, so that contour circles are formed. In the embodiment shown in fig. 5, the curved surface is higher near the axis of rotation R to form a boss, while the region farther from the axis of rotation R forms an annular recess 112. In order to insert the ball 2 into the through hole 110, the game participant should first let the designated ball 2 get rid of the limitation of the groove 112, at this time, the other balls 2 located in the groove 112 are not constrained and may become a source of interference, the inclination angle of the box 1 cannot be too large, otherwise the ball 2 located on the hole will get out of the through hole 110 and return to the groove 112. Therefore, the rotating surface of the third embodiment increases the operation difficulty of the player and increases the interest.

The identification symbol (not shown) of the ball 2 of the third embodiment is a color attached to the surface of the ball. The color round beads 2 have 7 particles: red, orange, yellow, green, cyan, blue and purple. After the box is shaken, the beads 2 can be sorted according to the following rules: the red beads 2 enter the through hole 110 in the center, and other beads 2 enter the peripheral through holes 110 sequentially in a clockwise sequence, namely orange, yellow, green, cyan, blue and purple. If the ball 2 is mistakenly inserted into the through hole, the ball 2 needs to be ejected by a finger and reordered. The cartridge 1 of the third embodiment can be used with other types of beads, for example, 7 beads 2 with a single color. The game participants only need to put the round beads 2 into the through holes 110 in sequence to complete the game task.

The embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to the above embodiments. The invention aims to realize grouping or sequencing of ball sets by using the through hole array to perform human intervention on the balls from the bottom. Those skilled in the art can develop many more embodiments with the understanding of this principle. Such embodiments may fall within the scope of the present invention.