CN216169900U - Movable top disk device - Google Patents

Abstract

The utility model discloses a movable gyro disk device, which comprises a device base, a gyro disk, an operating piece and a control piece, wherein the gyro disk is arranged on the device base; the gyro disk is at least partially movably connected to the device base, and the operating part is arranged on the device base and is positioned outside the area where the gyro disk is positioned; the control piece is movably connected to the device base and is positioned in the area where the spinning top disk is positioned; the operating part is linked with the control part, and the operating part drives the control part to move so as to control the gyro disk to move. When the movable gyro disk device is used, a player can control the gyro disk to move by operating the operating piece, so that the moving direction of a gyro in the gyro disk is controlled, the interactivity of the toy and the gyro in the playing process is improved, and the playing pleasure is increased.

Description

Movable top disk device

Technical Field

The utility model relates to the technical field of spinning top toys, in particular to an active spinning top disk device.

Background

In order to facilitate playing, the gyroscope is generally placed in a gyroscope disk for playing, and the existing gyroscope disk is a simple disk body with a fixed shape. When playing, the gyroscope rotates in the gyroscope disk, or a plurality of gyroscopes collide and fight in the gyroscope disk. In the process of playing, the top disk can not be controlled to move, so after the top is launched to the top disk, a player can only observe the rotation and fight conditions of the top in the top disk, the top in the top disk can not be controlled to move, interactivity is lacked, and the playing pleasure is reduced.

In view of the above, improvements are needed.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects of the prior art and provide the movable gyro disk device which can control the movement of the gyro disk and improve the interactivity and the playing pleasure.

The technical scheme of the utility model provides an active gyro disk device, which comprises a device base, a gyro disk, an operating piece and a control piece, wherein the gyro disk is arranged on the device base; the gyro disk is at least partially movably connected to the device base, and the operating part is installed on the device base and is positioned outside the area where the gyro disk is positioned; the control piece is movably connected to the device base and is positioned inside the area where the gyro disk is positioned; the operating part is linked with the control part, and the operating part drives the control part to move so as to control the gyro disk to move.

Further, the control part is arranged at the bottom of the gyro disk, and the control part can drive at least one part of the gyro disk to lift or lift.

Furthermore, each side of at least two opposite sides of the gyro disk is at least provided with a connecting part, each connecting part is connected with one control part, and the control part can drive the local lifting of the gyro disk at the corresponding position, so that the gyro disk is in an inclined shape.

Further, the control piece comprises a lifting mechanism and a pushing block, and the pushing block is connected to the upper end of the lifting mechanism; the operating piece is connected with the lifting mechanism through a linkage piece so as to control the lifting mechanism to lift; when the lifting mechanism ascends, the pushing block pushes the gyro disk upwards.

Further, the lifting mechanism comprises a first supporting rod, a second supporting rod, a swinging connecting rod and a sliding connecting rod which is rotatably connected with the swinging connecting rod; the swing connecting rod is rotationally connected with the device base, and the sliding connecting rod is slidably connected with the device base; the pushing block is positioned above the joint of the swinging connecting rod and the sliding connecting rod, the first supporting rod is rotatably connected between the swinging connecting rod and the pushing block, and the second supporting rod is rotatably connected between the sliding connecting rod and the pushing block; the linkage piece is connected with the sliding connecting rod, and when the linkage piece drives the sliding connecting rod to slide, the pushing block moves upwards or downwards.

Furthermore, a connecting rod is arranged on the sliding connecting rod, and the linkage piece is connected with the connecting rod; the device base is provided with a sliding groove, and the connecting rod is connected with the sliding groove.

Furthermore, an annular groove is formed in the connecting rod, a first linkage part is arranged on the linkage part, and the first linkage part is connected in the annular groove.

Further, the operating part comprises an operating button, a mounting seat and a movable block; the mounting seat is mounted on the device base, the movable block is movably connected to the mounting seat, and the linkage piece is connected between the movable block and the lifting mechanism; the operating button is positioned above the mounting seat and is in sliding connection with the device base; when the operating button is pressed, the operating button drives the movable block to move so as to control the linkage part to drive the lifting mechanism.

Further, the mounting seat is provided with a through hole; the movable block comprises a first movable part facing the operating button and a second movable part facing the linkage piece; the movable block is rotatably connected with the mounting seat, and the second movable part is connected with the linkage piece; when the operating button is pressed, the operating button is abutted to the first movable part, at least part of the first movable part moves into the through hole, and the first movable part drives the second movable part.

Furthermore, a connecting groove is formed in the second movable portion, a second linkage portion is arranged on the linkage piece, and the second linkage portion is connected in the connecting groove.

After adopting above-mentioned technical scheme, have following beneficial effect:

the technical scheme of the utility model provides the movable gyro disk device, at least part of the gyro disk is movably connected with the device base, and the movable gyro disk device is provided with the operating piece and the control piece to be linked with the gyro disk, so when the movable gyro disk device is used, a player can drive the control piece by operating the operating piece, and then the control piece controls the movement of the gyro disk, thereby realizing the control of the movement direction of a gyro in the gyro disk, improving the interactivity of a toy and the gyro in the playing process and increasing the playing pleasure.

Drawings

The disclosure of the present invention will become more readily understood by reference to the drawings. It should be understood that: these drawings are for illustrative purposes only and are not intended to limit the scope of the present disclosure. In the figure:

FIG. 1 is a perspective view of a removable spinning top disk assembly in accordance with one embodiment of the present invention;

FIG. 2 is an exploded view of a movable gyroscope disk according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of a spinning top according to an embodiment of the present invention;

FIG. 4 is a schematic view of an operating member, a control member and a linkage member according to an embodiment of the present invention;

FIG. 5 is a schematic view of a control member according to an embodiment of the present invention;

FIG. 6 is a schematic view of a chute according to an embodiment of the present invention;

FIG. 7 is an exploded view of an operating member according to an embodiment of the present invention;

FIG. 8 is a schematic view of a linkage member according to an embodiment of the present invention_。

Reference symbol comparison table:

movable top disk device 10

Device base 1 first seat part 11 second seat part 12 sliding groove 13

Operating member 3 operating button 31 of connecting part 21 of gyro disk 2

Mounting seat 32 through hole 321 movable block 33 first movable part 331

The second movable part 332 is connected with the groove 3321 and the control part 4 pushing block 41

First support rod 42, second support rod 43, swing link 44, slide link 45

First linkage part 51 of linkage 5 of annular groove 461 of connecting rod 46

The second linkage portion 52

Detailed Description

The following further describes embodiments of the present invention with reference to the accompanying drawings.

It is easily understood that according to the technical solution of the present invention, those skilled in the art can substitute various structures and implementation manners without changing the spirit of the present invention. Therefore, the following detailed description and the accompanying drawings are only exemplary illustrations of the technical solutions of the present invention, and should not be construed as being all of the present invention or as defining or limiting the technical solutions of the present invention.

The terms of orientation of up, down, left, right, front, back, top, bottom, and the like referred to or may be referred to in this specification are defined relative to the configuration shown in the drawings, and are relative terms, and thus may be changed correspondingly according to the position and the use state of the device. Therefore, these and other directional terms should not be construed as limiting terms.

As shown in fig. 1 to 7, an embodiment of the present invention is an active spinning top disk device 10, which includes a device base 1, a spinning top disk 2, an operating member 3 and a control member 4.

The spinning disk 2 is at least partially movably connected to the device base 1, and the operating element 3 is mounted on the device base 1 and outside the area of the spinning disk 2.

The control member 4 is movably connected to the base 1 of the device and is located inside the area of the spinning disk 2.

The operating part 3 is linked with the control part 4, and the operating part 3 drives the control part 4 to move so as to control the gyro disk 2 to move.

The active spinning top disk assembly 10 improves the interactivity between the player and the toy, increasing the interest in playing. The movable spinning top disk device 10 comprises a device base 1, a spinning top disk 2, an operating member 3 and a control member 4.

The device base 1 is intended to carry a spinning disk 2, an operating element 3 and a control element 4. The apparatus base body 1 includes a first seat portion 11 and a second seat portion 12 adjacent to the first seat portion 11. The spinning disk 2 is movably connected to the first seat portion 11, and the operating member 3 is movably connected to the second seat portion 12, outside the area where the spinning disk 2 is located. The first seat portion 11 is a region where the spinning top 2 is located, the second seat portion 12 may be located on one side or both sides of the first seat portion 11, or may surround the first seat portion 11 for one circle, and the operation element 3 is disposed at any position of the second seat portion 12.

The control member 4 is movably connected to the second seat portion 12 and is located inside the region of the top disk 2. Be provided with the control part on the control 4, the control part is connected with top dish 2, and the control part can be located top or below of top dish 2, can also be located top dish 2, and top dish 2 is provided with assembly groove or pilot hole promptly, and the control part stretches into assembly groove or pilot hole fit. The operating part 3 is connected with the control part 4, and the control part 4 is driven to move by the operating part 3.

When the movable gyro disk 2 is used, a player operates the operating part 3 to move, the operating part 3 drives the control part 4 to move, and the control part 4 drives the gyro disk 2 to move. When the gyro disk 2 moves, the gyro disk 2 influences the gyro movement in the gyro disk 2 to change the moving direction of the gyro. In this way, the player can control the movement of the top by himself, rather than just watching the random movement of the top, thereby increasing the interactivity between the player and the toy.

Optionally, the top disk 2 is movable in a manner of rotating on the device base 1, wherein the control member 4 is a turntable and the operation member 3 is a turntable lever. The rotating disc is rotatably connected to the first seat part 11, and the spinning top disc 2 is connected with the rotating disc. The turntable lever is connected to the side of the turntable and extends to the second housing portion 12. The player controls the rotating disc to rotate through the rotating disc rod. A left and right baffle plates are arranged on the surface of the top disk 2, and when the top disk 2 rotates, the baffle plates can be used for installing a top, so that the direction of the top is changed. Of course, the spinning top 2 may have other structures as long as the spinning top 2 can rotate.

Optionally, the movable gyroscope disk 2 is a part of a gyroscope toy device, the gyroscope toy device includes a driving mechanism for driving the gyroscope to rotate and an emitting mechanism for emitting the gyroscope onto the gyroscope disk 2, the driving mechanism and the emitting mechanism are installed on the second seat body portion 12, a gyroscope placing position is provided on the second seat body portion, and a driving output end of the driving mechanism and an emitting output end of the emitting mechanism can be connected with the gyroscope placing position. The driving mechanism can be a stay cord driving piece, the stay cord driving piece comprises a stay cord, a rope pulley and a driving gear set, the stay cord is wound on the rope pulley, and the driving gear set is meshed between the rope pulley and the gyroscope. The rope wheel drives the gyro to rotate through the driving gear set after the pull rope is pulled. The firing mechanism may be an ejection assembly. The ejection assembly includes a release button, a spring, a launch plate, and a locking member. The locking piece is unlocked by pressing the release button, and then the spring pushes the transmitting plate, so that the transmitting plate pushes the spinning top to leave the spinning top placing position.

Optionally, the movable gyro disk 2 is played in cooperation with an external gyro launcher provided with a drive mechanism and a launching mechanism.

In one embodiment, as shown in fig. 2-3, the control element 4 is disposed at the bottom of the spinning disk 2, and the control element 4 can lift or raise at least a portion of the spinning disk 2. The control part of the control part 4 is positioned at the bottom of the gyro disk 2, when the operation part 3 is controlled, the operation part 3 drives the control part 4 to move, the control part upwards pushes the gyro disk 2, part of the gyro disk 2 is lifted or raised, the whole gyro disk 2 is inclined, and a gyro on the gyro disk 2 moves under the action of gravity. The mode of controlling the movement of the gyro disk 2 is simpler and more convenient, and the manufacture is easy.

Optionally, the top disk 2 moves in a manner that a part of the top disk 2 tilts, and the top disk 2 is inclined as a whole. Wherein, the control part 4 is a mandril, and the operation part 3 is a pressing block. The push rod is rotatably connected to the first seat portion 11, wherein a first rod end of the push rod is located below the gyro disk 2, and a second rod end of the push rod extends into the second seat portion 12. The pressing block is connected with the second seat part 12 in a sliding mode and can slide on the second seat part 12 vertically. The pressing block is positioned above the second rod end, and when the pressing block is pressed downwards, the pressing block presses the second rod end. At this time, the second rod end moves downward, the first rod end moves upward, and the spinning top disk 2 is lifted upward, so that the spinning top disk 2 tilts up. The gyro in the gyro disk 2 moves toward the non-tilted side by gravity. Of course, the control member 4 and the operation member 3 may have other structures as long as the top disk 2 can be tilted.

In one embodiment, as shown in fig. 2-3, each of at least two opposite sides of the top plate 2 is provided with at least one connecting portion 21, each connecting portion 21 is connected to one control member 4, and the control member 4 can drive the top plate 2 at the corresponding position to be partially lifted, so that the top plate 2 is inclined. .

Specifically, the bottom of the spinning top disk 2 has two connecting portions 21, and the two connecting portions 21 are disposed opposite to each other. One of the connection portions 21 is defined as a first linkage portion 51 and the other connection portion 21 is defined as a second linkage portion 52 for convenience of description. The gyro disk 2 is movable up and down on the apparatus base 1, the first linkage portion 51 is connected to the control member 4, and the second linkage portion 52 is movably connected to the apparatus base 1. When the control member 4 controls the first linkage portion 51 to move upward, the first linkage portion 51 is located above the second linkage portion 52, so that the gyro disk 2 is inclined, and at this time, the gyro on the gyro disk 2 moves in a direction approaching the second linkage portion 52. The arrangement can accurately control the movement direction of the gyroscope.

Optionally, a base groove is provided on the device base 1, and the gyro disk 2 is located in the base groove and is in clearance fit with the base groove. The first linkage part 51 is hinged or overlapped with the side wall of the base groove, the second linkage part 52 is slidably connected with the base groove, and the control part 4 is hinged or overlapped with the second linkage part 52.

Optionally, a blocking wall is connected to a wall of the base groove, the blocking wall is higher than the top disk 2, and the blocking wall can block the top in the top disk 2 to prevent the top from being separated from the top disk 2.

In one embodiment, as shown in fig. 2-3, two operating members 3 and two control members 4 are included. The two operating parts 3 are respectively linked with the two control parts 4, and the two control parts 4 are respectively hinged with the two connecting parts 21. When one of the control pieces 4 drives the gyro disk 2 to move, the gyro disk 2 is inclined.

Specifically, the movable spinning top disk device 10 includes two operating members 3 and two control members 4, and each operating member 3 controls one control member 4 to move. For convenience of description, one of the control members 4 is defined as a first control member, and the other control member 4 is defined as a second control member. The first control member is connected to the first linkage portion 51, and the second control member is connected to the second linkage portion 52. When only the first control member drives the gyro disk 2 to move, the first linkage portion 51 moves upward, the first linkage portion 51 is located above the second linkage portion 52, the gyro disk 2 tilts, and a gyro in the gyro disk 2 moves toward a direction close to the second linkage portion 52. When only the second control member drives the gyro disk 2 to move, the second linkage portion 52 moves upward, the second linkage portion 52 is located above the first linkage portion 51, the gyro disk 2 tilts, and a gyro in the gyro disk 2 moves toward a direction close to the first linkage portion 51. When the first control piece and the second control piece simultaneously drive the gyro disk 2 to move, the first linkage part 51 and the second linkage part 52 simultaneously move upwards, at this time, the gyro disk 2 keeps a horizontal state, and the gyro in the gyro disk 2 stops moving. So set up, make the control top that the player can be more nimble remove.

In one embodiment, as shown in fig. 2 and 4-5, the control member 4 includes a lifting mechanism and a pushing block 41, and the pushing block 41 is connected to an upper end of the lifting mechanism. The operating piece 3 is connected with the lifting mechanism through a linkage piece 5 to control the lifting mechanism to lift. When the lifting mechanism is lifted, the top pushing block 41 pushes the top plate 2 upward.

Specifically, the movable top disk device 10 further includes a linkage member 5, and the linkage member 5 is located between the operating member 3 and the control member 4. The control member 4 is composed of a lifting mechanism and a pushing block 41, and the pushing block 41 is connected to the lifting end of the lifting mechanism and can move up and down along with the lifting of the lifting end. When the lifting mechanism is lifted, the top pushing block 41 pushes the top plate 2 upward, so that the top plate 2 is inclined. So set up, can promote top dish 2 more effectively steadily.

Optionally, the lifting mechanism comprises a gear member and a sliding rack, and the linkage member 5 is a wheel and operates as a rocking handle. The sliding rack is slidably connected to the device base 1, which is a lifting end. The gear piece is engaged between the rotating wheel and the sliding rack, and the rocking handle is connected to the rotating wheel. The player can rotate the runner through the rocking handle, and the runner drives gear spare to rotate, makes the slip rack can slide from top to bottom. Of course, the lifting mechanism may have other structures as long as the lifting can be controlled by the operating element 3.

In one embodiment, as shown in fig. 2 and 4-5, the lifting mechanism includes a first support rod 42, a second support rod 43, a swing link 44, and a slide link 45 rotatably connected to the swing link 44. The swing link 44 is rotatably connected to the apparatus base 1, and the slide link 45 is slidably connected to the apparatus base 1. The pushing block 41 is located above the connection position of the swinging link 44 and the sliding link 45, the first supporting rod 42 is rotatably connected between the swinging link 44 and the pushing block 41, and the second supporting rod 43 is rotatably connected between the sliding link 45 and the pushing block 41. The linkage piece 5 is connected with the sliding connecting rod 45, and when the linkage piece 5 drives the sliding connecting rod 45 to slide, the pushing block 41 moves upwards or downwards.

Specifically, the lifting mechanism is composed of a first support rod 42, a second support rod 43, a swing link 44, and a slide link 45. Wherein, the swing link 44 and the sliding link 45 are crossed and are rotatably connected through a first rotating shaft. The bottom end of the swing connecting rod 44 is rotatably connected with the device base 1 through a second rotating shaft, and the top end of the swing connecting rod 44 is rotatably connected with the first supporting rod 42 through a third rotating shaft. The bottom end of the sliding connecting rod 45 is connected with the device base 1 in a sliding mode, and the top end of the sliding connecting rod 45 is connected with the second supporting rod 43 in a rotating mode through a fourth rotating shaft. The top end of the first supporting rod 42 and the top end of the second supporting rod 43 are rotatably connected with the pushing block 41 through a fifth rotating shaft. The link 5 is connected to the bottom end of the slide link 45.

When the linkage 5 drives the bottom end of the sliding link 45 to slide in a direction approaching the swinging link 44, the first support rod 42, the second support rod 43, the swinging link 44 and the sliding link 45 swing upward to push the pushing block 41 to move upward. The lifting mechanism is simple in structure and small in occupied space, and the ejector block 41 can move stably in the vertical direction.

Alternatively, the pushing block 41 is hinged to the connecting portion 21 of the top disk 2, so that the pushing block 41 is firmly connected to the top disk 2.

In one embodiment, as shown in fig. 5-6, the sliding link 45 is provided with a connecting rod 46, and the linkage 5 is connected with the connecting rod 46. The device base 1 is provided with a sliding groove 13, and the connecting rod 46 is connected with the sliding groove 13.

Specifically, the device base 1 is provided with a slide for sliding the slide link 45, and a slide groove 13 is provided on a wall surface of the slide. The connecting rod 46 is connected to the side of the sliding link 45 and extends through the sliding slot 13 to the outside of the slideway. The portion of the connecting rod 46 located within the slide channel 13 is slidably connected to the slide channel 13. The linkage piece 5 is connected with the connecting rod 46, and the linkage piece 5 pulls the connecting rod 46 to drive the sliding connecting rod 45 to slide. So set up, the overall arrangement is more reasonable, and spout 13 has limiting displacement to connecting rod 46 moreover, avoids sliding connecting rod 45 to excessively remove. The length of the sliding groove 13 is proportional to the rising height of the pushing block 41, and the higher the rising height of the pushing block 41 is along with the extension of the length of the sliding groove 13, the larger the inclination angle of the top disk 2 is. The ratio of the length of the chute 13 to the height of the pusher 41 is related to the lengths of the first support rod 42, the second support rod 43, the swing link 44, and the slide link 45 of the lifting mechanism.

In one embodiment, as shown in fig. 4-5 and 8, the connecting rod 46 is provided with an annular groove 461, the linkage member 5 is provided with a first linkage portion 51, and the first linkage portion 51 is connected in the annular groove 461.

Specifically, one end of the linkage 5 facing the connecting rod 46 is a first linkage portion 51, and the first linkage portion 51 is connected in the annular groove 461 and fixed with the connecting rod 46. The annular recess 461 prevents the linkage and the connecting rod 46 from being separated.

Optionally, the first linking portion 51 is hook-shaped, and can hook the connecting rod 46 and is located in the annular recess 461. This facilitates the mounting of the linkage 5 with the connecting rod 46.

Alternatively, the link 5 is a connecting string, and the first link 51 can be wound in the annular groove 461.

Alternatively, a guide wheel is provided between the operating member 3 and the connecting rod 46, the guide wheel being rotatably connected to the device base 1, and a portion of the pull cord being wound around the guide wheel.

In one embodiment, as shown in fig. 4-6, the operating member 3 includes an operating button 31, a mounting seat 32, and a movable block 33. The mounting seat 32 is installed on the device base 1, the movable block 33 is movably connected on the mounting seat 32, and the linkage piece 5 is connected between the movable block 33 and the lifting mechanism. The operation button 31 is located above the mount 32 and slidably connected to the apparatus base 1. When the operating button 31 is pressed, the operating button 31 drives the movable block 33 to move, so as to control the linkage 5 to drive the lifting mechanism.

Specifically, the mounting seat 32 is provided on the apparatus base 1, the operation button 31 is slidably attached to the apparatus base 1 and located above the mounting seat 32, and the operation button 31 can slide up and down. The link 5 is slidably attached to the apparatus base 1 below the mount 32. The movable block 33 is movably connected to the mounting base 32. When the operating button 31 is pressed, the operating button 31 pushes the movable block 33 to move, and the movable block 33 slides the link 5, so that the lifting mechanism is lifted. So set up, simple structure makes things convenient for player control, has improved the participation degree when the player plays moreover.

Optionally, the movable block 33 is a wedge block, and the wedge block is slidably connected with the mounting seat 32. The linkage piece 5 is a linkage rod, and a wedge-shaped groove matched with the shape of the wedge-shaped block is formed in the linkage rod. When the operating button 31 is pressed, the operating button 31 pushes the wedge block to move downwards, and the wedge block is inserted into the wedge-shaped groove to drive the linkage rod to slide.

In one embodiment, as shown in fig. 4 and 7, the mounting seat 32 is provided with a through hole 321. The movable block 33 includes a first movable portion 331 facing the operation button 31 and a second movable portion 332 facing the link 5. The movable block 33 is rotatably connected to the mounting base 32, and the second movable portion 332 is connected to the link 5. When the operation button 31 is pressed, the operation button 31 abuts against the first movable portion 331, at least a part of the first movable portion 331 moves into the through hole 321, and the first movable portion 331 moves the second movable portion 332.

Specifically, the first movable portion 331 and the second movable portion 332 are vertically connected, and the first movable portion 331 is located above the second movable portion 332. The movable block 33 is rotatably coupled to the mount 32.

Alternatively, the movable block 33 is connected in the through hole 321, or a connecting seat is provided on the mounting seat 32, and the movable block 33 is rotatably connected to the connecting seat.

When the operation button 31 is pressed, the operation button 31 presses the first movable portion 331 downward, and the first movable portion 331 rotates downward into the through hole 321. The first movable portion 331 rotates downward to drive the second movable portion 332 to rotate upward, so that the second movable portion 332 drives the linking member 5 to slide. So set up, movable block 33's simple structure is changeed the manufacturing, reduces manufacturing cost.

Alternatively, the link 5 is a pulling rope, and the pulling rope is wound around the second movable portion 332.

Alternatively, the linkage 5 is a linkage rack, and the second movable portion 332 has a connecting tooth portion in a sector shape, which is engaged with the linkage rack.

In one embodiment, as shown in fig. 7 to 8, the second movable portion 332 is provided with a connecting groove 3321, the link 5 is provided with a second link portion 52, and the second link portion 52 is connected in the connecting groove 3321.

Specifically, the end of the link 5 toward the second movable portion 332 is the second link portion 52. Two ribs are provided at intervals on the second movable portion 332, and a connection groove 3321 is formed between the two ribs. The second linkage portion 52 is connected in the connection recess 3321, so that the linkage 5 is firmly connected with the second movable portion 332 and is not easily separated.

Alternatively, the link 5 is a pulling rope, and the pulling rope is wound in the connection groove 3321.

In summary, the present invention discloses an active spinning top disk device 10, which comprises a device base 1, a spinning top disk 2, an operating member 3 and a control member 4. The spinning disk 2 is at least partially movably connected to the device base 1, and the operating element 3 is mounted on the device base 1 and outside the area of the spinning disk 2. The control member 4 is movably connected to the base 1 of the device and is located inside the area of the spinning disk 2. The operating part 3 is linked with the control part 4, and the operating part 3 drives the control part 4 to move so as to control the gyro disk 2 to move. The movable spinning top disk device 10 changes the conventional mode in which only the spinning top can be seen in the spinning top disk 2. Can control top dish 2 activity through operation operating parts 3, change the moving direction of top in top dish 2, increase the interactivity between player and the toy. When a plurality of gyros in the gyro disk 2 fight against each other, the multiple gyros in the gyro disk 2 can collide with each other more violently through the activity of the gyro disk 2, so that the play pleasure is improved.

The foregoing is considered as illustrative only of the principles and preferred embodiments of the utility model. It should be noted that, for those skilled in the art, several other modifications can be made on the basis of the principle of the present invention, and the protection scope of the present invention should be regarded.

Claims (10)

1. A movable spinning top disk device (10) is characterized by comprising a device base (1), a spinning top disk (2), an operating piece (3) and a control piece (4);

the gyro disk (2) is at least partially movably connected to the device base (1), and the operating part (3) is mounted on the device base (1) and is located outside the area where the gyro disk (2) is located;

the control element (4) is movably connected to the device base (1) and is located inside the area where the gyro disk (2) is located;

the operating part (3) is linked with the control part (4), and the operating part (3) drives the control part (4) to move so as to control the gyro disk (2) to move.

2. Movable spinning top disc device (10) according to claim 1, characterised in that said control member (4) is arranged at the bottom of said spinning top disc (2), said control member (4) being able to lift or lift at least a part of said spinning top disc (2).

3. Movable spinning top disc device (10) according to claim 2, wherein at least one connection portion (21) is provided on each of at least two opposite sides of said spinning top disc (2), each of said connection portions (21) being connected to one of said control members (4), said control members (4) being adapted to locally lift said spinning top disc (2) in a corresponding position, so that said spinning top disc (2) is tilted.

4. The removable spinning top disk apparatus (10) of claim 1 wherein said control member (4) includes a lift mechanism and a pusher (41), said pusher (41) being connected at an upper end of said lift mechanism;

the operating piece (3) is connected with the lifting mechanism through a linkage piece (5) to control the lifting mechanism to lift;

when the lifting mechanism ascends, the pushing block (41) pushes the gyro disk (2) upwards.

5. The removable spinning top disk assembly (10) of claim 4 wherein said lifting mechanism includes a first support rod (42), a second support rod (43), a swing link (44), and a slide link (45) rotatably connected to said swing link (44);

the swing connecting rod (44) is rotatably connected with the device base (1), and the sliding connecting rod (45) is slidably connected with the device base (1);

the pushing block (41) is positioned above the joint of the swinging connecting rod (44) and the sliding connecting rod (45), the first supporting rod (42) is rotatably connected between the swinging connecting rod (44) and the pushing block (41), and the second supporting rod (43) is rotatably connected between the sliding connecting rod (45) and the pushing block (41);

the linkage piece (5) is connected with the sliding connecting rod (45), and when the linkage piece (5) drives the sliding connecting rod (45) to slide, the pushing block (41) moves upwards or downwards.

6. A movable spinning top disc device (10) according to claim 5, wherein said sliding link (45) is provided with a connecting rod (46), said linkage (5) being connected to said connecting rod (46);

the device is characterized in that a sliding groove (13) is formed in the device base (1), and the connecting rod (46) is connected with the sliding groove (13).

7. A movable spinning top disc device (10) according to claim 6, wherein said connecting rod (46) is provided with an annular groove (461), said linkage member (5) is provided with a first linkage portion (51), said first linkage portion (51) being connected within said annular groove (461).

8. The movable spinning top disk device (10) according to claim 4, wherein said operating member (3) comprises an operating button (31), a mounting seat (32) and a movable block (33);

the mounting seat (32) is mounted on the device base (1), the movable block (33) is movably connected to the mounting seat (32), and the linkage piece (5) is connected between the movable block (33) and the lifting mechanism;

the operating button (31) is positioned above the mounting seat (32) and is connected with the device base (1) in a sliding manner;

when the operation button (31) is pressed, the operation button (31) drives the movable block (33) to move so as to control the linkage piece (5) to drive the lifting mechanism.

9. The removable spinning top disk apparatus (10) of claim 8, wherein said mounting base (32) is provided with a through hole (321);

the movable block (33) comprises a first movable portion (331) facing the operating button (31) and a second movable portion (332) facing the link (5);

the movable block (33) is rotatably connected with the mounting seat (32), and the second movable part (332) is connected with the linkage piece (5);

when the operation button (31) is pressed, the operation button (31) is abutted against the first movable part (331), at least part of the first movable part (331) moves into the through hole (321), and the first movable part (331) drives the second movable part (332).

10. The removable spinning top disk assembly (10) of claim 9, wherein said second removable portion (332) is provided with a connecting recess (3321), said linkage member (5) is provided with a second linkage portion (52), and said second linkage portion (52) is connected within said connecting recess (3321).

Images