WO2024001269A1

WO2024001269A1 - Spinning top toy

Info

Publication number: WO2024001269A1
Application number: PCT/CN2023/079564
Authority: WO
Inventors: 谢国华; 谢幼兰; 陈佳瑜
Original assignee: 广州灵动创想文化科技有限公司
Priority date: 2022-06-30
Filing date: 2023-03-03
Publication date: 2024-01-04
Also published as: CN117357910A

Abstract

A spinning top toy, comprising a spinning top accelerator (100) and a spinning top body (200) movably connected to the spinning top accelerator (100). The spinning top accelerator (100) comprises an enclosure (10) and, arranged in the enclosure (10), a driving device (20), a clamping assembly (30) and a push-ejecting assembly (40); the driving device (20) comprises a housing (21) and an acceleration gear set (22), the acceleration gear set (22) being rotatably arranged in the housing (21); a gravity block (23) is slidably provided on the housing (21), and the gravity block (23) is in driving connection with the acceleration gear set (22); the clamping assembly (30) is in driven connection with the acceleration gear set (22), and the clamping assembly (30) is used for movably clamping the spinning top body (200); the push-ejecting assembly (40) is used for push-ejecting the spinning top body (200); when swung to slide on the housing (21) to and fro, the gravity block (23) drives the acceleration gear set (22) to rotate, thereby driving the clamping assembly (30) to rotate. The spinning top toy has ingenious design, conducts multiple times of driving acceleration in a swinging mode, and is easy and convenient to operate, providing a spinning top with a more novel, interesting, convenient and fun playing method.

Description

A spinning top toy

Technical field

The present invention relates to the technical field of toys, and in particular to a spinning top toy.

Background technique

Toys are tools for intellectual development and entertainment. With the continuous improvement of people's living standards, users' pursuit of the quality and functionality of toys is also getting higher and higher. Among them, ejection toys based on tops have attracted a large number of fans and users due to animation movies and their unique gameplay.

However, existing projectile toys usually use rack acceleration to accelerate the rotation of the top. Specifically, the rack first passes through the driving gear, and then the rack is pulled to drive the driving gear to rotate, and then the driving gear drives the top to rotate and accelerate. This kind of gyro toy can usually only be accelerated once. After the rack is pulled out, it cannot be accelerated twice, causing the gyro to be unable to obtain more rotational potential energy. In addition, the user must use both hands to drive through the rack acceleration. In this way, the driving acceleration of the top is cumbersome, time-consuming and labor-intensive, which reduces the fun of the top toy.

Contents of the invention

Based on this, the purpose of the present invention is to overcome the shortcomings of the existing technology and provide a gyro toy with an ingenious design, multiple drive accelerations through swinging, and easy operation, making the gyro gameplay more novel, interesting, convenient and fun.

In order to achieve the above objects, the technical solutions adopted by the present invention are:

A gyro toy, including a gyro accelerator and a gyro body movably connected with the gyro accelerator; the gyro accelerator includes a shell and a driving device, a clamping component and a push component arranged in the casing; the driving device includes a shell and an accelerator Gear set, the acceleration gear set is rotatably arranged in the housing, a gravity block is slidably provided on the housing, the gravity block is drivingly connected to the acceleration gear set; the clamping assembly It is transmission connected with the acceleration gear set, and the clamping component is used to movablely clamp the gyro body; the push component is used to push the gyro body; when the gravity block slides back and forth on the housing by swinging the gravity block, The gravity block drives the acceleration gear set to rotate, which in turn drives the clamping assembly to rotate.

As an embodiment, the acceleration gear set is rotatably disposed inside the housing, a first opening is provided on one side of the housing, and at least a part of the acceleration gear set extends out of the first opening of the housing. Outside an opening; a first driving rack is provided on one side of the gravity block, and the first driving rack is cooperatively and transmission connected with a portion of the acceleration gear set extending out of the opening of the housing.

As an embodiment, the acceleration gear set includes a first driving gear, a first clutch gear and a driving gear, the housing is provided with a first arc-shaped chute, and the first driving gear and the driving gear are respectively rotatable. is disposed in the housing, and the first driving gear meshes with the first clutch gear; the first clutch gear is slidably disposed in the first arc-shaped chute , when the first clutch gear slides to one end of the first arc-shaped chute, the first clutch gear meshes with the driving gear, and when the first clutch gear slides to other positions of the first arc-shaped chute, the first clutch gear and the driving gear are not in contact with each other; at least a part of the first driving gear extends out of the first opening of the housing, and a part of the first driving gear extending out of the first opening is in contact with the first driving rack of the gravity block Match the transmission connection.

As an embodiment, the other side of the housing is provided with a second opening, the other side of the gravity block is provided with a second drive rack, and the acceleration gear set further includes a second driving gear and a second Clutch gear, the housing is provided with a second arc-shaped chute, the second clutch gear is slidably disposed in the second arc-shaped chute, and the second clutch gear meshes with the second driving gear ; When the second clutch gear slides to one end of the second arc-shaped chute, the second clutch gear meshes with the driving gear. When the second clutch gear slides to other positions of the second arc-shaped chute, the second clutch gear meshes with the driving gear. The drive gears do not touch each other.

As an embodiment, at least a part of the second driving gear extends out of the second opening of the housing, and a part of the second driving gear extending out of the second opening cooperates with the second driving rack of the gravity block. Transmission connection; the second driving gear, the second clutch gear and the second arcuate chute are respectively arranged symmetrically with the first driving gear, the first clutch gear and the first arcuate chute relative to the driving gear.

As an implementation manner, guide slide bars are provided in parallel on both sides of the housing, and both sides of the gravity block are slidably sleeved on the guide slide bars on both sides of the housing.

As an embodiment, the clamping assembly includes a magnetic sleeve, which is drivingly connected to the acceleration gear set; the magnetic sleeve is a cylindrical structure with an open lower end, and the magnetic sleeve is A magnetic unit is provided on the top of the inner wall of the barrel, and a magnet unit is provided on the top of the gyro body. The gyro body is adsorbed and connected to the magnetic unit of the magnetic sleeve through the magnet unit on the top.

As an embodiment, the clamping assembly further includes a transmission gearbox and a passive gear rotatably arranged in the transmission gearbox. The transmission gearbox is fixed below the acceleration gear set of the driving device. The passive gearbox The gear is drivingly connected to the acceleration gear set, and the driven gear is coaxially and fixedly connected to the magnetic sleeve.

As an embodiment, one or more transmission gears are provided between the driven gear and the acceleration gear set, and the driven gear, one or more transmission gears and the acceleration gear set are sequentially connected in transmission.

As an embodiment, the housing is a cavity structure with upper and lower openings. The ejection assembly includes a ejection rod and a return spring. The upper end of the ejection rod is located at the upper opening of the housing. The middle part of the ejection rod The return spring is connected to the inner wall of the housing, and the lower end of the ejection rod is located on the outer peripheral side of the magnetic sleeve.

Therefore, in the gyro toy of the present invention, the driving device swings the gravity block back and forth, so that the gravity block continuously accelerates the rotation of the acceleration gear set, specifically through the driving teeth on one side or both sides of the gravity block. The strips drive and accelerate the acceleration gear set respectively, and one or two clutch gears in the acceleration gear set ensure the one-way rotation of the driving gear. rotation, thereby avoiding the two-way rotation of the driving gear due to the back and forth swing of the gravity block, so that the operation of the driving gear always maintains one-way rotation; then the clamping assembly is driven by the driving device to rotate, and at the same time the clamping assembly can drive the gyro body. Rotate and store energy, and launch the gyroscope after rotation and energy storage through the push-ejection assembly, making the gyro toy of the present invention easy to operate, and the driving method is novel and interesting, which expands the functionality and fun of the driving device, and has a high market promotion value.

For better understanding and implementation, the present invention will be described in detail below with reference to the accompanying drawings.

Description of drawings

Figure 1 is a schematic diagram of the internal structure of the top toy of the present invention;

Figure 2 is another schematic diagram of the internal structure of the top toy of the present invention;

Figure 3 is a schematic diagram of the external structure of the top toy of the present invention;

Figure 4 is a schematic structural diagram of the gyro accelerator of the gyro toy of the present invention;

Figure 5 is a schematic structural diagram of the push component of the top toy of the present invention;

Figure 6 is a schematic diagram of the connection between the driving device of the top toy of the present invention and the top body;

Figure 7 is a schematic structural diagram of the driving device of the gyro toy of the present invention;

Figure 8 is another structural schematic diagram of the driving device of the gyro toy of the present invention;

Figure 9 is an exploded schematic diagram of the driving device of the gyro toy of the present invention;

Figure 10 is a schematic structural diagram of the housing of the driving device of the gyro toy of the present invention;

Figure 11 is a schematic structural diagram of the acceleration gear set of the driving device of the gyro toy of the present invention;

Figure 12 is a schematic diagram of the bottom structure of the clamping assembly of the top toy of the present invention;

Figure 13 is a schematic diagram of the internal structure of the clamping component of the top toy of the present invention;

Figure 14 is a schematic structural diagram of the top body of the top toy of the present invention;

Figure 15 is an exploded schematic diagram of the top body of the top toy of the present invention;

Figure 16 is a schematic diagram of the connection between the driving device and the gyroscope body in Embodiment 3 of the present invention.

Detailed ways

To further explain various embodiments, the present invention provides drawings. These drawings are part of the disclosure of the present invention, and are mainly used to illustrate the embodiments, and can be used to explain the operating principles of the embodiments in conjunction with the relevant descriptions in the specification. With reference to these contents, those of ordinary skill in the art will be able to understand other possible implementations and advantages of the present invention.

In the description of the present invention, it should be understood that the terms "center", "longitudinal", "transverse", "length", "width", "thickness", "upper", "lower", "left", " The orientation or positional relationships indicated by "right", "top", "bottom", "inner", "outer", "axial", "radial", "circumferential", etc. are based on the orientation or position shown in the drawings relationship is only for the convenience of describing the present invention and simplifying This description does not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operate in a specific orientation, and therefore no limitations on the invention should be construed.

Example 1

Please refer to Figures 1 to 15. Figure 1 is a schematic diagram of the internal structure of the top toy of the present invention; Figure 2 is a schematic diagram of the internal structure of the top toy of the present invention; Figure 3 is a schematic diagram of the external structure of the top toy of the present invention; Figure 4 is a schematic diagram of the external structure of the top toy of the present invention. The structural schematic diagram of the gyro accelerator of the gyro toy of the present invention; Figure 5 is the structural schematic diagram of the ejection component of the gyro toy of the present invention; Figure 6 is the connection schematic diagram of the driving device of the gyro toy of the present invention and the gyro body; Figure 7 is the connection diagram of the gyro toy of the present invention. A schematic structural view of the driving device; Figure 8 is another schematic structural view of the driving device of the gyro toy of the present invention; Figure 9 is an exploded schematic view of the driving device of the gyro toy of the present invention; Figure 10 is a schematic view of the casing of the driving device of the gyro toy of the present invention. Structural schematic diagram; Figure 11 is a schematic structural diagram of the acceleration gear set of the driving device of the gyro toy of the present invention; Figure 12 is a schematic structural diagram of the bottom of the clamping component of the gyro toy of the present invention; Figure 13 is the inside of the clamping component of the gyro toy of the present invention Structural schematic diagram; Figure 14 is a schematic structural diagram of the top body of the top toy of the present invention; Figure 15 is an exploded schematic diagram of the top body of the top toy of the present invention.

This embodiment provides a gyro toy, which includes a gyro accelerator 100 and a gyro body 200 movably connected to the gyro accelerator 100; the gyro accelerator 100 includes a shell 10 and a driving device 20, a clamping assembly 30 and a pusher disposed in the shell 10. Shooting assembly 40, the driving device 20 includes a housing 21 and an acceleration gear set 22. The acceleration gear set 22 is rotatably provided in the housing 21, and a gravity block is slidably provided on the housing 21. 23. The gravity block 23 is transmission connected to the acceleration gear set 22; the clamping component 30 is transmission connected to the acceleration gear set 22, and the clamping component 30 is used to movable clamp the gyro body 200 ; The push assembly 40 is used to push the gyro body 200; when the gravity block 23 slides back and forth on the housing 21 by swinging, the gravity block 23 drives the acceleration gear set 22 to rotate, thereby driving the clamping assembly 30 to rotate.

Specifically, the acceleration gear set 22 is rotatably disposed inside the housing 21 , a first opening is provided on one side of the housing 21 , and at least a portion of the acceleration gear set 22 extends out of the housing 21 outside the first opening; a first driving rack 231 is provided on one side of the gravity block 23, and the first driving rack 231 is cooperatively and transmission connected with a portion of the acceleration gear set 22 extending out of the opening of the housing 21.

In order to ensure that the output end of the acceleration gear set 22 can rotate in one direction when the gravity block 23 slides back and forth on the housing 21, the acceleration gear set 22 in this embodiment includes a first driving gear 24, a first clutch gear 25 and a driving gear 26 , the housing 21 is provided with a first arc-shaped chute 211, the first driving gear 24 and the driving gear 26 are respectively rotatably provided in the housing 21, and the first driving gear 24 and the first clutch gear 25 mesh; the first clutch gear 25 is slidably disposed in the first arcuate chute 211. When the first clutch gear 25 slides to one end of the first arcuate chute 211, the first clutch gear 25 and The driving gear 26 is engaged, and when the first clutch gear 25 slides to other positions of the first arc-shaped chute 211, the A clutch gear 25 and a driving gear 26 do not contact each other.

Further, at least a part of the first driving gear 24 extends out of the first opening of the housing 21 , and a part of the first driving gear 24 extending out of the first opening is in contact with the first driving rack of the gravity block 23 231 matches the transmission connection. Among them, in order to enable the gravity block 23 to better drive the first driving gear 24 when sliding back and forth, the first opening of this embodiment is provided in the middle of one side of the housing 21, and the first driving tooth of this embodiment The length of the bar 231 is slightly longer than half the length of one side of the housing 21. In this way, when the gravity block 23 slides back and forth, since the first opening is located in the middle of one side of the housing 21, the length of the first driving rack 231 is just right. It is longer than half the length of one side of the housing 21, so that the first driving rack 231 is always meshed with the first driving gear 24, and when the first driving rack 231 slides back and forth, it can drive the first driving gear 24 to rotate evenly. It is half the length of one side of the housing 21 , so that the gravity block 23 can better drive the first driving gear 24 .

It should be noted that the first opening in this embodiment is not limited to being opened in the middle of one side of the housing 21, but can also be opened in other positions on one side of the housing 21. Correspondingly, the first driving tooth in this embodiment The length of the bar 231 is not limited to the above length, and driving racks of other lengths can also be used.

Therefore, the acceleration gear set 22 of this embodiment is provided with a slidable first clutch gear 25, and a first arc-shaped chute 211 matching the first clutch gear 25 is provided on the housing 21, so that , the rotating shaft of the first clutch gear 25 can slide in the first arc-shaped chute 211. In addition, the first driving gear 24 of this embodiment is always meshed with the first clutch gear 25. In this way, when the gravity block 23 slides along the left direction, the first driving rack 231 drives the first driving gear 24 clockwise. At the same time, the first driving gear 24 drives the first clutch gear 25 to rotate counterclockwise. At this time, the first clutch gear 25 slides to the first arc-shaped chute 211 close to the driving gear 26 under the pushing action of the first driving gear 24. One end is meshed with the driving gear 26, and at the same time, due to the pushing effect of the first driving gear 24, the first clutch gear 25 and the driving gear 26 are always meshed. That is to say, when the gravity block 23 slides to the left, the first driving rack 231 drives the first driving gear 24, the first clutch gear 25 and the driving gear 26 to rotate in sequence.

When the gravity block 23 slides along the right direction, the first driving rack 231 drives the first driving gear 24 to rotate counterclockwise, and at the same time the first driving gear 24 drives the first clutch gear 25 to rotate clockwise. At this time, the first clutch gear 25 Under the pushing action of the first driving gear 24, the first arc-shaped chute 211 slides to an end away from the driving gear 26 and is not in contact with the driving gear 26. Due to the pushing action of the first driving gear 24, the first The clutch gear 25 and the drive gear 26 are always separated. That is to say, when the gravity block 23 slides to the right, the first driving rack 231 drives the first driving gear 24 and the first clutch gear 25, and the driving gear 26 continues to maintain the state of separation from the first clutch gear 25. Turn in the original direction.

Therefore, in this embodiment, the position of the first arc-shaped chute 211 is cleverly set, and when the first clutch gear 25 moves to one end of the first arc-shaped chute 211, the first clutch gear 25 meshes with the driving gear 26. When the first clutch gear 25 slides to other positions of the first arc-shaped chute 211, the first clutch gear 25 and the driving gear 26 do not contact each other, so that the gravity The block 23 always keeps the rotation direction of the drive gear 26 unchanged when sliding back and forth.

In addition, in the acceleration gear set 22 of this embodiment, one or more first driven gears 241 are driveably connected between the first driving gear 24 and the first clutch gear 25 .

Optionally, first protrusions 214 are provided at both ends of the side of the housing 21 with the first opening, and a guide slide bar 213 is provided between the two first protrusions 214. The gravity block 23 is slidable. It is sleeved on the guide slide rod 213 of the housing 21 . In this embodiment, a first guide seat 234 is provided between the first driving rack 231 of the gravity block 23 and the gravity block 23. The first guide seat 234 is provided with a first guide hole. A guide hole is slidably sleeved in the guide slide rod 213 .

Therefore, by providing two first bumps 214, the housing 21 of this embodiment can serve as an installation structure for the guide slide bar 213, and can also serve as a limiting structure for the first driving rack 231, which can effectively prevent the first The driving rack 231 slides out of the guide slide rod 213, making the reciprocating sliding of the gravity block 23 safe and effective.

In order to make the gravity block 23 slide more smoothly, in this embodiment, one or more sliding wheels 233 are provided at the bottom of the gravity block 23 , and the gravity block 23 is slidably disposed on the bottom of the gravity block 23 through the one or more sliding wheels 233 . In this way, the surface-to-surface contact friction between the gravity block 23 and the housing 21 is avoided, making the sliding movement of the gravity block 23 relative to the housing 21 smoother.

In order to further ensure the smooth and stable sliding of the gravity block 23, the other side of the housing 21 in this embodiment is also provided with the guide slide bar 213, and the guide slide bars 213 on both sides of the housing 21 are relatively parallel; correspondingly Ground, second protrusions 215 are respectively provided at both ends of the other side of the housing 21, the guide slide rod 213 is provided between the two second protrusions 215, and a third protrusion 215 is provided at the bottom of the other side of the gravity block 23. Two guide seats 235 are provided with second guide holes. In this way, both sides of the gravity block 23 are slidably sleeved on the housing through the first guide holes and the second guide holes respectively. 21 on the guide slide rods 213 on both sides. Combined with one or more sliding wheels 233 at the bottom of the gravity block 23, the sliding of the gravity block 23 relative to the housing 21 is more stable and smooth, which is also beneficial to the first driving rack 231 and the acceleration gear set of the gravity block 23. 22 mesh drive.

In this embodiment, the gyro accelerator 100 includes a housing 10 with upper and lower openings. The housing 21 of the driving device 20 is fixed inside the housing 10. The clamping assembly 30 includes a transmission gearbox 31 and a magnetic sleeve. 32. The transmission gear box 31 is fixed below the housing 21 of the driving device 20, and the bottom of the housing 21 is provided with a through hole. The transmission gear box 31 is rotatably provided with a driven gear 33. The driven gear 33 is meshed and connected with the driving gear 26 of the driving device 20; the magnetic sleeve 32 is arranged below the transmission gear box 31, and the magnetic sleeve 32 is coaxially fixedly connected with the driven gear 33. Therefore, the magnetic sleeve 32 of this embodiment is used to attract and hold the gyroscope body 200 .

Further, in this embodiment, the magnetic sleeve 32 has a cylindrical structure with an open lower end, and a magnetic unit 34 is provided on the top of the inner wall of the magnetic sleeve 32. In addition, the gyro body 200 of this embodiment has The middle of the top protrudes upward to set up magnetic suction The magnetic protruding column 50 is provided with the magnet unit 51 inside. In this way, the magnetic suction unit 34 in the magnetic suction sleeve 32 can be used to absorb the gyro body 200 with the magnet unit 51 on the top. The gyroscope body 200 is adsorbed and fixed. Therefore, the gyro accelerator 100 of this embodiment can drive the driven gear 33 to rotate through the driving gear 26 of the driving device 20, and at the same time drive the magnetic sleeve 32 to rotate, and then drive the gyro body 200 that is adsorbed and clamped by the magnetic sleeve 32. Carry out rotational energy storage.

In order to ensure the stability of the connection between the gyro body 200 and the magnetic sleeve 32, in this embodiment, the magnetic protrusions 50 of the gyro body 200 have a polygonal cylinder structure. Correspondingly, the magnetic sleeve The interior of 32 is a polygonal cavity structure. In this way, when the magnetic sleeve 32 is adsorbed and connected to the gyroscope body 200, the polygonal cylinder structure design can effectively prevent the two from being displaced from each other during rotation.

In addition, the push assembly 40 of this embodiment includes a push rod 41 and a return spring 42. The upper end of the push rod 41 is located at the upper end opening of the housing 10. The middle part of the push rod 41 passes through the return spring 42 and the housing 10. The inner wall of the push rod 41 is connected, and the lower end of the push rod 41 is located on the outer peripheral side of the magnetic sleeve 32. Therefore, by pressing the upper end of the push rod 41 downward, the push rod 41 moves downward and compresses the return spring 42. At the same time, The lower end of the push rod 41 moves downward quickly and can quickly push the top in the magnetic sleeve 32 out from the lower end opening of the housing 10; after loosening the upper end of the push rod 41, the push rod 41 presses against the return spring 42 Quickly move up and reset under the action.

Further, in order to reduce the friction force generated when the push rod 41 pushes the gyro body 200, in this embodiment, an arc-shaped push ring 43 is provided at the bottom of the push rod 41, and the arc-shaped push ring 43 is located at A number of pulleys 44 are provided at intervals on the outer peripheral side of the magnetic sleeve 32 and the bottom of the arc-shaped push ring 43. In this way, when the arc-shaped push ring 43 of the push rod 41 is about to touch the gyro body 200 that tells the rotation When the gyro body 200 rotates at a high speed, the pulleys 44 at the bottom of the arc-shaped push ring 43 can first contact the gyro body 200, and the pulleys 44 can be driven to rotate under the high-speed rotation of the gyro body 200. This can greatly reduce the push rod 41 from pushing the gyro body. The friction force generated at 200 ℃ thus preserves more of the rotational potential energy of the gyroscope body 200 .

In this embodiment, the driving device 20 keeps shaking left and right by the shell 10 of the gyro accelerator 100 held by the user, and then under the action of inertia, the gravity block 23 keeps sliding left and right along with the shell 10 to perform reciprocating motion, and at the same time drives The acceleration gear set 22 rotates, so that the driving gear 26 of the acceleration gear set 22 drives the passive gear 33 to rotate, and finally drives the gyro body 200 in the magnetic sleeve 32 to rotate and store energy. The stored gyro body 200 can be ejected by pushing Rod 41 pushes it out.

Furthermore, in this embodiment, the magnetic connection between the magnetic sleeve 32 and the gyro body 200 is provided, so that the gyro body 200 after being ejected can be quickly recovered to continue to accelerate and store energy. During the specific operation, only the magnetic suction is required. The opening of the sleeve 32 is roughly aligned with the magnetic protrusions 50 of the rotating gyro body 200, and the gyro body 200 can be quickly re-adsorbed and clamped in the magnetic sleeve 32 under the magnetic attraction of the two, and through Shake the shell 10 left and right again to re-accelerate the rotation of the top body 200, thereby making the top toy of the present invention more entertaining and playable.

Optionally, in this embodiment, one or more third driven gears 35 may be disposed between the driven gear 33 and the driving gear 26 . In order to clearly distinguish the rocking direction of the gravity block 23, recessed portions 11 are provided on both sides of the housing 10 in this embodiment. The connection line of the two recessed portions 11 is parallel to the sliding direction of the gravity block 23. In this way, the user can Each recess 11 can distinguish the swing direction of the gravity block 23.

Therefore, in the gyro toy of this embodiment, the driving device 20 swings the gravity block 23 back and forth, so that the gravity block 23 continuously accelerates the rotation of the acceleration gear set 22, specifically through the rotation of the gravity block 23 on one side. The first driving rack 231 drives and accelerates the accelerating gear set 22, and the first clutch gear 25 in the accelerating gear set 22 ensures the one-way rotation of the driving gear 26, thus avoiding the risk of damage due to the back and forth swing of the gravity block 23. The bidirectional rotation of the driving gear 26 keeps the operation of the driving gear 26 in one direction, and drives the passive gear 33 and the magnetic sleeve 32 to rotate synchronously, thereby accelerating and accumulating the gyro body 200 adsorbed in the magnetic sleeve 32 Finally, the charged gyro body 200 is ejected from the lower end opening of the housing 10 through the ejection rod 41 . Therefore, the gyro toy of the present invention is easy to operate, has a novel and interesting driving method, expands the functionality and fun of the driving device 20, and has high marketing value.

Example 2

Please refer to Figures 1 to 15. This embodiment is basically the same as Embodiment 1. The difference is that in this embodiment, a second opening is provided on the other side of the housing 21, and a second opening is provided on the other side of the gravity block 23. A second driving rack 232. The acceleration gear set 22 also includes a second driving gear 27 and a second clutch gear 28. The housing 21 is provided with a second arcuate chute 212. The second clutch gear 28 can Slidingly disposed in the second arcuate chute 212, and the second clutch gear 28 meshes with the second driving gear 27; when the second clutch gear 28 slides to one end of the second arcuate chute 212, The second clutch gear 28 meshes with the driving gear 26. When the second clutch gear 28 slides to other positions of the second arc-shaped slide groove 212, the second clutch gear 28 and the driving gear 26 do not contact each other.

In this embodiment, at least a part of the second driving gear 27 extends out of the second opening of the housing 21 , and a part of the second driving gear 27 extending out of the second opening is in contact with the second part of the gravity block 23 . The driving rack 232 is connected with transmission; the second driving gear 27, the second clutch gear 28 and the second arcuate chute 212 are connected with the first driving gear 24, the first clutch gear 25 and the first arcuate chute. 211 are respectively arranged symmetrically with respect to the driving gear 26 .

That is to say, compared with Embodiment 1, the housing 21 of this embodiment is provided with a second opening and a second arc-shaped chute 212, and the second opening is provided in the middle of the other side of the housing 21. The two arc-shaped chute 212 and the first arc-shaped chute 211 are arranged symmetrically with respect to the driving gear 26; and the acceleration gear set 22 of this embodiment is provided with a second driving gear 27 and a second clutch gear 28, and the second The driving gear 27 and the second clutch gear 28 are arranged symmetrically with the first driving gear 24 and the first clutch gear 25 in Embodiment 1 with respect to the driving gear 26; correspondingly, the other side of the gravity block 23 is arranged There is a second driving rack 232, and the second guide seat 235 is provided between the second driving rack 232 and the gravity block 23, The second driving rack 232 and the first driving rack 231 are arranged symmetrically with respect to the housing 21 .

Therefore, when the gravity block 23 of this embodiment slides along the left direction, the first driving rack 231 drives the first driving gear 24 to rotate clockwise, and at the same time, the first driving gear 24 drives the first clutch gear 25 to rotate counterclockwise. At this time, the first clutch gear 25 slides to one end of the first arc-shaped chute 211 close to the driving gear 26 under the pushing action of the first driving gear 24 and meshes with the driving gear 26. At the same time, due to the The pushing effect makes the first clutch gear 25 and the driving gear 26 always mesh. The second driving rack 232 drives the second driving gear 27 to rotate counterclockwise, and at the same time the second driving gear 27 drives the second clutch gear 28 to rotate clockwise. At this time, the second clutch gear 28 is pushed by the second driving gear 27 Slide down to one end of the second arc-shaped chute 212 away from the driving gear 26 and out of contact with the driving gear 26, and due to the pushing effect of the second driving gear 27, the second clutch gear 28 and the driving gear 26 are always separated. .

That is to say, when the gravity block 23 drives the first driving rack 231 and the second driving rack 232 to slide to the left, the first driving rack 231 drives the driving gear 26 to rotate, and due to the interaction between the second clutch gear 28 and the driving gear 23 The gears 26 are not in contact with each other, and the second clutch gear 28 is idling so that the second driving rack 232 does not drive the driving gear 26 to rotate.

When the gravity block 23 slides along the right direction, the first driving rack 231 drives the first driving gear 24 to rotate counterclockwise, and at the same time the first driving gear 24 drives the first clutch gear 25 to rotate clockwise. At this time, the first clutch gear 25 Under the pushing action of the first driving gear 24, the first arc-shaped chute 211 slides to an end away from the driving gear 26 and is not in contact with the driving gear 26. Due to the pushing action of the first driving gear 24, the first The clutch gear 25 and the drive gear 26 are always separated. The second driving rack 232 drives the second driving gear 27 to rotate clockwise, and at the same time the second driving gear 27 drives the second clutch gear 28 to rotate counterclockwise. At this time, the second clutch gear 28 is pushed by the second driving gear 27 Slide down to one end of the second arc-shaped chute 212 close to the driving gear 26 and mesh with the driving gear 26, and under the pushing action of the second driving gear 27, the second clutch gear 28 is always meshed with the driving gear 26. , thereby allowing the second driving rack 232 to drive the second driving gear 27, the second clutch gear 28 and the driving gear 26 to rotate in sequence.

That is to say, when the gravity block 23 drives the first driving rack 231 and the second driving rack 232 to slide to the right, since the first clutch gear 25 and the driving gear 26 are in a separated state, the first driving rack 231 drives The first driving gear 24 and the first clutch gear 25 are idling. The second driving rack 232 drives the second driving gear 27, the second clutch gear 28 and the driving gear 26 to rotate in sequence, and causes the driving gear 26 to continue to rotate in the original direction. Moreover, driven by the second driving rack 232, the second driving gear 27 continues to drive the driving gear 26 to rotate through the second clutch gear 28, so that the gravity block 23 always moves the driving gear 26 in a single direction during the reciprocating sliding process. of driving energy storage.

Therefore, in this embodiment, the first driving gear 24, the first clutch gear 25, the first arc-shaped chute 211, the second driving gear 27, the second clutch gear 28, and the second arc-shaped chute 212 are respectively relative to the driving gear. 26 are arranged symmetrically, and the first driving rack 231 and the second driving rack 232 of the gravity block 23 are arranged symmetrically with respect to the housing 21, so that when the gravity block 23 slides back and forth, the driving gear 26 always keeps the rotation direction unchanged. Change.

Furthermore, one or more second driven gears 271 are driveably connected between the second driving gear 27 and the second clutch gear 28 in this embodiment. In order to better connect the driven gear 33 of the transmission gearbox 31, the driving gear 26 of this embodiment can also be transmission connected with one or more output gears 29.

Therefore, in the gyro toy of this embodiment, the driving device 20 swings the gravity block 23 back and forth, so that the gravity block 23 continuously accelerates the rotation of the acceleration gear set 22, specifically through the two sides of the gravity block 23. The drive rack structure drives and accelerates the acceleration gear set 22 respectively, and the two clutch gears in the acceleration gear set 22 ensure the one-way rotation of the drive gear 26, thereby avoiding the back and forth swing of the gravity block 23 causing the drive gear to rotate. 26 rotates in both directions, so that the operation of the driving gear 26 always maintains one-way rotation, and drives the passive gear 33 and the magnetic sleeve 32 to rotate synchronously, thereby accelerating the energy storage of the gyro body 200 adsorbed in the magnetic sleeve 32, Finally, the charged gyro body 200 is ejected from the lower end opening of the housing 10 through the ejection rod 41 . Therefore, the gyro toy of the present invention is easy to operate, has a novel and interesting driving method, expands the functionality and fun of the driving device 20, and has high marketing value.

Example 3

Please refer to FIG. 16 , which is a schematic diagram of the connection between the driving device and the gyroscope body in Embodiment 3 of the present invention. This embodiment is basically the same as Embodiment 1 or 2. The difference lies in that: the bottom of the magnetic sleeve 322 in this embodiment is provided with an annular zigzag magnetic unit 342, and the top surface of the gyro body 300 in this embodiment is An annular zigzag magnet unit 60 is provided. In this way, the gyro body 300 of this embodiment can be magnetically adsorbed on the magnetic unit 342 of the magnetic sleeve 322 through the magnet unit 60 on the top, and can be connected to the magnetic unit 342 through the magnet unit 60. The mutual interlocking of the magnetic suction units 342 makes the magnetic suction sleeve 322 and the gyroscope body 300 in this embodiment relatively more stable during synchronous rotation and less prone to displacement.

The above-mentioned embodiments only express several implementation modes of the present invention. The descriptions are relatively specific and detailed, but should not be understood as limiting the scope of the invented top toy. It should be noted that, for those of ordinary skill in the art, several modifications and improvements can be made without departing from the concept of the present invention, and these all belong to the protection scope of the present invention.

Claims

A spinning top toy, which is characterized by:

It includes a gyro accelerator and a gyro body movably connected with the gyro accelerator; the gyro accelerator includes a housing and a driving device, a clamping component and a push component arranged in the housing; the driving device includes a housing and an acceleration gear set; The acceleration gear set is rotatably arranged in the housing, and a gravity block is slidably provided on the housing, and the gravity block is drivingly connected to the acceleration gear set; the clamping assembly is connected to the acceleration gear The group transmission connection is connected, and the clamping component is used to movablely clamp the gyro body; the push component is used to push the gyro body;

When the gravity block slides back and forth on the housing by swinging, the gravity block drives the acceleration gear set to rotate, thereby driving the clamping assembly to rotate.
The top toy according to claim 1, characterized in that:

The acceleration gear set is rotatably disposed inside the housing, a first opening is provided on one side of the housing, and at least a portion of the acceleration gear set extends out of the first opening of the housing; A first driving rack is provided on one side of the gravity block, and the first driving rack is cooperatively and transmission connected with a portion of the acceleration gear set extending outside the opening of the housing.
The top toy according to claim 2, characterized in that:

The acceleration gear set includes a first driving gear, a first clutch gear and a driving gear. The housing is provided with a first arc-shaped chute. The first driving gear and the driving gear are respectively rotatably arranged in the housing. , and the first driving gear meshes with the first clutch gear; the first clutch gear is slidably disposed in the first arc-shaped chute, and when the first clutch gear slides to one end of the first arc-shaped chute, , the first clutch gear meshes with the driving gear, and when the first clutch gear slides to other positions of the first arc-shaped chute, the first clutch gear and the driving gear do not contact each other; at least a part of the first driving gear extends out Outside the first opening of the housing, and a portion of the first driving gear extending outside the first opening is cooperatively and transmission-connected with the first driving rack of the gravity block.
The top toy according to claim 3, characterized in that:

The other side of the housing is provided with a second opening, the other side of the gravity block is provided with a second driving rack, the acceleration gear set also includes a second driving gear and a second clutch gear, the housing The body is provided with a second arc-shaped chute, the second clutch gear is slidably disposed in the second arc-shaped chute, and the second clutch gear meshes with the second driving gear; when the second clutch gear When sliding to one end of the second arc-shaped chute, the second clutch gear meshes with the driving gear. When the second clutch gear slides to other positions of the second arc-shaped chute, the second clutch gear and the driving gear do not contact each other.
The top toy according to claim 4, characterized in that:

At least a part of the second driving gear extends out of the second opening of the housing, and the second driving gear extends out of the second opening. The outer part is cooperatively and transmission connected with the second driving rack of the gravity block; the second driving gear, the second clutch gear and the second arc chute are connected with the first driving gear, the first clutch gear and the third An arc-shaped chute is arranged symmetrically with respect to the driving gear.
The top toy according to claim 1, characterized in that:

Guide sliding rods are provided in parallel on both sides of the housing, and both sides of the gravity block are slidably sleeved on the guiding sliding rods on both sides of the housing.
The top toy according to claim 1, characterized in that:

The clamping assembly includes a magnetic sleeve, which is drivingly connected to the acceleration gear set; the magnetic sleeve is a cylindrical structure with an open lower end, and the top of the inner wall of the magnetic sleeve is provided with A magnet unit is provided on the top of the gyro body, and the gyro body is adsorbed and connected to the magnetic unit of the magnetic sleeve through the magnet unit on the top.
The top toy according to claim 7, characterized in that:

The clamping assembly also includes a transmission gearbox and a driven gear rotatably arranged in the transmission gearbox. The transmission gearbox is fixed below the acceleration gear set of the driving device. The driven gear and the acceleration gear The set is transmission connected, and the driven gear is coaxially and fixedly connected with the magnetic sleeve.
The top toy according to claim 8, characterized in that:

One or more transmission gears are arranged between the driven gear and the acceleration gear set, and the driven gear, one or more transmission gears and the acceleration gear set are connected in sequence.
The top toy according to claim 7, characterized in that:

The housing is a cavity structure with upper and lower openings. The ejection assembly includes an ejection rod and a return spring. The upper end of the ejection rod is located at the upper end opening of the housing. The middle part of the ejection rod is connected to the return spring through the return spring. The inner wall of the housing is connected, and the lower end of the push rod is located on the outer peripheral side of the magnetic sleeve.