WO2024001268A1 - Driving apparatus, spinning top accelerator, and spinning top toy - Google Patents

Abstract

A driving apparatus (100), a spinning top accelerator (200), and a spinning top toy. The driving apparatus (100) comprises a housing (10), a base (20), and an acceleration gear set (30). The base (20) is provided in the housing (10), the acceleration gear set (30) is rotatably provided on the base (20), a gravity ball (40) is slidably provided on the base (20), and the gravity ball (40) is connected to the acceleration gear set (30) by means of a linkage rod (41); and when the gravity ball (40) is driven to do circular motion on the base (20), the gravity ball (40) drives the acceleration gear set (30) to rotate by means of the linkage rod (41). The driving apparatus is ingeniously designed to perform multiple driving accelerations by shaking the gravity ball (40), and is simple and convenient to operate, so that a playing method of a spinning top is more novel, interesting, convenient, and fun.

Description

A driving device, gyro accelerator and gyro toy Technical field

This solution relates to the technical field of toys, in particular to a driving device, a gyro accelerator and a gyro 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 drive device can usually only perform one-time acceleration. After the rack is pulled out, it cannot accelerate 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. This makes the driving and acceleration of the gyro more cumbersome, time-consuming and labor-intensive, and reduces the fun of the gyro.

Program content

Based on this, the purpose of this solution is to overcome the shortcomings of the existing technology and provide a driving device that is ingeniously designed to perform multiple driving accelerations by shaking the gravity ball and is easy to operate, making the gyro gameplay more novel, interesting and convenient Fun.

In order to achieve the above purpose, the technical solutions adopted in this plan are:

A driving device includes a housing, a base and an acceleration gear set. The base is provided in the housing. The acceleration gear set is rotatably provided on the base. The base is slidably mounted on the base. A gravity ball is provided, and the gravity ball is connected to the acceleration gear set through a linkage rod; when the gravity ball is driven to make a circular motion on the base, the gravity ball drives the acceleration gear set to rotate through the linkage rod.

As an embodiment, one end of the linkage rod is fixedly connected to the acceleration gear set, the other end of the linkage rod is provided with a U-shaped clamping opening, and the gravity ball is rotatably arranged on the U-shaped clamping port of the linkage rod. In the mouth.

As an embodiment, the acceleration gear set is rotatably arranged in the middle of the base. An annular chute is provided on the upper surface of the base with the middle of the base as the center. The radius of the annular chute is consistent with the center of the base. The linkage rods have the same length, the gravity ball is slidably disposed in the annular chute, and the gravity ball makes a circular motion with the acceleration gear set as the center.

As an embodiment, the acceleration gear set includes a linkage rotating shaft and a driving gear. The linkage rotating shaft is rotatably disposed on the base through a bearing structure, and the linkage rotating shaft is fixedly connected to the linkage rod; The driving gear is coaxially fixed and sleeved on the linkage rotating shaft.

As an embodiment, the acceleration gear set further includes a driven gear, the driven gear is rotatably disposed in the housing, and the driven gear is meshed with the driving gear.

As an embodiment, one or more transmission gears are provided between the driving gear and the driven gear, the one or more transmission gears are rotatably provided in the housing, and the driving gear, a Or multiple transmission gears and driven gears are meshed and connected in sequence.

Therefore, the driving device described in this solution drives the gravity ball to make a circular motion by rotating in a circular motion, and then drives the acceleration gear set to rotate synchronously through the linkage rod, and drives the gravity ball to make a circular motion by constantly shaking the housing, so that The gravity ball rotates faster and faster under the action of inertia, causing the acceleration gear set to rotate faster and faster. This allows the driving device of this solution to drive and accelerate the acceleration gear set through shaking, and enables the acceleration gear set to output It has large rotational potential energy, is easy to operate, and has novel and interesting driving methods, which expands the functionality and fun of the driving device and has high market promotion value.

In addition, this solution also provides a gyro accelerator, which includes a driving device as described in any one of the above, an adsorption component for adsorbing the gyro, and a push component for launching the gyro; the driving device is In order to drive the adsorption component to rotate, the push component is telescopically disposed on the housing.

As an embodiment, the adsorption component includes a connecting rod, an adsorption iron plate and an adsorption magnet. The upper end of the connecting rod is coaxially fixedly connected to the acceleration gear set of the driving device, and the lower end of the connecting rod is coaxially fixed with the acceleration gear set of the driving device. The adsorption iron plate is fixedly connected, the bottom of the adsorption iron plate is used to adsorb the top, the adsorption magnet is magnetically connected to the adsorption iron plate, and the adsorption magnet is movably set on the connecting rod; the pushing The assembly is used to push the adsorption magnet away from the adsorption iron plate.

As an embodiment, the push-and-eject assembly includes a push rod, a return spring, and a push-off rod. The push rod is telescopically disposed in the housing through the return spring, and one end of the push rod Extending out of the shell, the other end of the push rod is against the upper end of the push-off rod; the middle part of the push-off rod is rotatably arranged in the housing, and the lower end of the push-off rod is provided with The hooking part is located below the adsorption magnet; when the push rod is pressed to drive the push-off lever to rotate, the push-off lever drives the adsorption magnet upward through the hook part at the bottom and connects with the adsorption magnet. The iron plate is separated.

Therefore, the gyro accelerator of this solution uses a circular shaking method to drive the gravity ball of the driving device to make a circular motion, and then drives the acceleration gear set to rotate synchronously through the linkage rod, and drives the gravity ball to make a circular motion by constantly shaking the shell. The gravity ball rotates faster and faster under the action of inertia. At the same time, the rotational potential energy obtained by the accelerating gear set becomes larger and larger. The accelerating gear set drives the adsorption component to rotate synchronously. In this way, the gyroscope adsorbed by the adsorption component also obtains The gyro accelerator of this solution has a large rotational potential energy and can eject the energy-charged gyro through the ejection component, making the gyro accelerator of this solution novel and interesting, and easy to operate. It expands the functionality and interest of the gyro accelerator and has a relatively high High marketing value.

Furthermore, this solution also provides a gyro toy, which includes the gyro accelerator as described in any one of the above items, and also includes a top, which is magnetically connected to the adsorption iron plate.

For better understanding and implementation, this solution is described in detail below with reference to the accompanying drawings.

Description of drawings

Figure 1 is a schematic structural diagram of the driving device of this solution;

Figure 2 is another structural schematic diagram of the driving device of this solution;

Figure 3 is a schematic structural diagram of the acceleration gear set of the driving device of this solution;

Figure 4 is a schematic structural diagram of the housing of the driving device of this solution;

Figure 5 is a schematic diagram of the external structure of the gyro accelerator of this solution;

Figure 6 is a schematic diagram of the internal structure of the gyro accelerator of this solution;

Figure 7 is a schematic diagram of the component connections of the gyro accelerator in this solution;

Figure 8 is a schematic diagram of the connection of another component of the driving device of this solution;

Figure 9 is a schematic diagram of the internal structure of the gyro toy according to this solution;

Figure 10 is an exploded schematic diagram of the gyro toy according to this solution;

Figure 11 is an exploded schematic diagram of the top of the top toy of this solution.

Detailed ways

To further explain each embodiment, this solution is provided with drawings. These drawings are part of the disclosure content of this solution, 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 should be able to understand other possible implementations and the advantages of this solution.

In the description of this scheme, it needs to 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 The relationship is only for the convenience of describing the present solution and simplifying the description, but does not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and therefore no limitation on the present solution can be understood.

Please refer to Figures 1 to 11. Figure 1 is a schematic structural view of the driving device of this solution; Figure 2 is another structural schematic view of the driving device of this solution; Figure 3 is a schematic structural view of the acceleration gear set of the driving device of this solution; Figure 4 is A schematic structural diagram of the housing of the driving device of this solution; Figure 5 is a schematic diagram of the external structure of the gyro accelerator of this solution; Figure 6 is a schematic diagram of the internal structure of the gyro accelerator of this solution; Figure 7 is a schematic diagram of the component connections of the gyro accelerator of this solution; Figure 8 is Another component connection diagram of the driving device in this solution; Figure 9 is a schematic diagram of the internal structure of the gyro toy in this solution; Figure 10 is an exploded schematic view of the gyro toy in this solution; Figure 11 is an exploded schematic view of the top of the gyro toy in this solution.

Example 1

As shown in Figures 1 to 4, this embodiment provides a driving device 100, which includes a housing 10, a base 20 and an acceleration gear. Group 30, the base 20 is disposed in the housing 10, the acceleration gear set 30 is rotatably disposed on the base 20, a gravity ball 40 is slidably disposed on the base 20, the The gravity ball 40 is connected to the acceleration gear set 30 through a linkage rod 41; when the gravity ball 40 is driven to make a circular motion on the base 20, the gravity ball 40 drives the acceleration gear set 30 to rotate through the linkage rod 41. In this embodiment, the housing 10 is a cylindrical structure with an open lower end.

Specifically, one end of the linkage rod 41 is fixedly connected to the acceleration gear set 30 , the other end of the linkage rod 41 is provided with a U-shaped clamping opening 42 , and the gravity ball 40 is rotatably provided at the U of the linkage rod 41 type clamping port 42. In this embodiment, the two inner sides of the U-shaped clamping opening 42 are respectively provided with rotation axes, and the two sides of the gravity ball 40 are respectively provided with movable sleeve holes corresponding to the two rotation axes. In this way, the gravity ball 40 can be rotatably sleeved on the two rotating axes of the U-shaped clamping port 42 through the movable sleeve holes on both sides.

Optionally, the acceleration gear set 30 is rotatably disposed in the middle of the base 20 , and an annular chute 21 is provided on the upper surface of the base 20 with the middle of the base 20 as the center. The annular chute 21 The radius of is the same as the length of the linkage rod 41 , the gravity ball 40 is slidably disposed in the annular chute 21 , and the gravity ball 40 makes a circular motion with the acceleration gear set 30 as the center.

In this embodiment, the acceleration gear set 30 includes a linkage rotating shaft 31 and a driving gear 32. The linkage rotating shaft 31 is rotatably disposed on the base 20 through a bearing structure, and the linkage rotating shaft 31 is connected to the linkage rotating shaft 31. The rod 41 is fixedly connected; the driving gear 32 is coaxially fixed and sleeved on the linkage shaft 31 . The base 20 of this embodiment has a disk-shaped structure, and the base 20 of this embodiment is horizontally disposed inside the housing 10 . The upper end of the linkage shaft 31 passes through the center of the base 20 and Extending above the base 20, one end of the linkage rotating shaft 31 extending above the base 20 is relatively vertically fixedly connected to the linkage rod 41; the lower end of the linkage rotating shaft 31 extends below the base 20, and the driving gear The fixed sleeve 32 is provided at one end of the linkage shaft 31 extending below the base 20 .

Further, the acceleration gear set 30 further includes a driven gear 33 , the driven gear 33 is rotatably disposed in the housing 10 , and the driven gear 33 is engaged with the driving gear 32 . Among them, one or more transmission gears 34 are provided between the driving gear 32 and the driven gear 33 . The one or more transmission gears 34 are rotatably provided in the housing 10 , and the driving gear 32 , one or more transmission gears 34, and the driven gear 33 are meshed and connected in sequence.

Therefore, the driving device 100 of this embodiment drives the gravity ball 40 to move in a circular motion by rotating in a circle, and then drives the acceleration gear set 30 to rotate synchronously through the linkage rod 41, and drives the gravity ball by continuously rotating and shaking the housing 10. 40 makes a circular motion, causing the gravity ball 40 to rotate faster and faster under the action of inertia, and at the same time, the linkage shaft 31 of the acceleration gear set 30 rotates faster and faster. In this way, the linkage shaft 31 drives the driving gear 32 to rotate at the same time, and then through The driving gear 32 drives the driven gear 33 to rotate, and finally outputs a large rotational potential energy through the driven gear 33 . Compared with the prior art, the driving device 100 of this solution drives and accelerates the acceleration gear set 30 by shaking, and makes the acceleration gear set 30 can output a large rotational potential energy, is easy to operate, and has a novel and interesting driving method, which expands the functionality and interest of the driving device 100 and has high marketing value.

It should be noted that the driving device 100 of this embodiment is not limited to driving the driven gear 33 to output rotational potential energy through the driving gear 32 , but can also directly output rotational potential energy through the linkage shaft 31 .

Example 2

This embodiment provides a gyro accelerator 200, which includes the driving device 100 described in Embodiment 1, an adsorption component 50 for adsorbing the gyro, and a push component 60 for launching the gyro; the driving The device 100 is used to drive the adsorption assembly 50 to rotate, and the push assembly 60 is telescopically disposed on the housing 10 .

In this embodiment, the adsorption component 50 includes a connecting rod 51, an adsorbing iron plate 52 and an adsorbing magnet 53. The upper end of the connecting rod 51 is coaxially fixedly connected to the acceleration gear set 30 of the driving device 100. The lower end of the connecting rod 51 is fixedly connected to the adsorption iron plate 52. The bottom of the adsorption iron plate 52 is used to adsorb the top. The adsorption magnet 53 is magnetically connected to the adsorption iron plate 52, and the adsorption magnet 53 is movable. Set on the connecting rod 51 , the push assembly 60 is used to push the adsorption magnet 53 away from the adsorption iron plate 52 .

The upper end of the connecting rod 51 of the adsorption assembly 50 is coaxially and fixedly connected to the driven gear 33 of the acceleration gear set 30 . In this way, the circular motion of the gravity ball 40 can drive the linked rotating shaft of the acceleration gear set 30 31 rotates synchronously, and then drives the driven gear 33 to rotate through the driving gear 32 fixedly connected to the linkage shaft 31, and then drives the connecting rod 51 to rotate synchronously through the driven gear 33, and finally drives the adsorption iron plate 52 to rotate through the connecting rod 51. The bottom of the adsorption magnet 53 is adsorbed and fixed to the top of the adsorption iron plate 52, so that the adsorption magnet 53 and the adsorption iron plate 52 rotate synchronously. In this way, the adsorption magnet 53 imparts the magnetic attraction function to the adsorption iron plate 52, so that The adsorbing iron plate 52 can absorb the top and drive the top to rotate.

Further, the push and launch assembly 60 includes a push rod 61, a return spring 62 and a push away rod 63. The push rod 61 is telescopically arranged in the housing 10 through the return spring 62, and the push rod 61 is telescopically installed in the housing 10 through the return spring 62. One end of the push rod 61 extends out of the housing 10 , and the other end of the push rod 61 is against the upper end of the push-off rod 63 ; the middle part of the push-off rod 63 is rotatably disposed on the housing 10 , and the lower end of the push-off lever 63 is provided with a hooking portion 64, which is located below the adsorption magnet 53; when the push-off lever 61 is pressed to drive the push-off lever 63 to rotate, the push-off lever 63 passes through The protruding portion 64 at the bottom drives the adsorption magnet 53 to move upward and separate from the adsorption iron plate 52 .

In this embodiment, since the adsorption magnet 53 is movably sleeved on the connecting rod 51, when the push rod 61 is pressed to drive the push-off rod 63 to rotate, the hook 64 at the bottom of the push-off rod 63 The adsorption magnet 53 can be driven to move upward and separate from the adsorption iron plate 52, so that the adsorption iron plate 52 does not have the magnetic attraction function. At this time, the top at the bottom of the adsorption iron plate 52 naturally breaks away from the adsorption iron plate 52, thereby causing the rotation of the iron plate 52 to accumulate. The powered gyroscope can be launched.

Compared with the prior art, the gyro accelerator 200 of this embodiment drives the gravity ball 40 of the driving device 100 to move in a circular motion by rotating and shaking, and then drives the acceleration gear set 30 to rotate synchronously through the linkage rod 41, and through constant shaking The housing 10 drives the gravity ball 40 to perform circular motion, so that the gravity ball 40 rotates faster and faster under the action of inertia. At the same time, the rotational potential energy obtained by the linkage shaft 31 of the acceleration gear set 30 also becomes larger and larger, and then through the acceleration gear set 30 The adsorption component 50 is driven to rotate synchronously. In this way, the gyro adsorbed by the adsorption component 50 also obtains a greater rotational potential energy, and the energy-charged gyro can be pushed out through the push component 60, making the gyro accelerator of this solution The gameplay of 200 is novel and interesting, and the operation is simple, which expands the functionality and fun of gyro accelerator 200 and has high marketing value.

Example 3

This embodiment provides a gyro accelerator 200. The gyro accelerator 200 of this embodiment is basically the same as the gyro accelerator 200 of Embodiment 2. The difference is that in the gyro accelerator 200 of this embodiment, the adsorption iron plate 52 is directly connected to the gyro accelerator 200. The bottom of the linkage rotating shaft 31 of the acceleration gear set 30 is fixedly connected, and the adsorption magnet 53 is movably sleeved on the lower end of the linkage rotating shaft 31 . That is to say, compared with the gyro accelerator 200 of Embodiment 2, the gyro accelerator 200 of this embodiment directly outputs rotational potential energy through the linkage shaft 31 , instead of outputting rotational potential energy through the driving gear 32 and the drive gear 32 as in the gyro accelerator 200 of Embodiment 2. The moving gear 33 outputs rotational potential energy and has a simpler structure.

Therefore, the gyro accelerator 200 of this embodiment drives the gravity ball 40 of the driving device 100 to move in a circular motion by rotating in a circular motion, and then drives the accelerating gear set 30 to rotate synchronously through the linkage rod 41, and continuously shakes the housing 10. The gravity ball 40 is driven to perform a circular motion, causing the gravity ball 40 to rotate faster and faster under the action of inertia. At the same time, the linkage shaft 31 of the acceleration gear set 30 obtains greater and greater rotational potential energy, and then drives the adsorption assembly 50 through the acceleration gear set 30 Rotate synchronously. In this way, the gyroscope adsorbed by the adsorption component 50 also obtains a greater rotational potential energy, and the energy-charged gyroscope can be ejected through the ejection component 60, making the gyro accelerator 200 of this solution novel. It is interesting and easy to operate, expands the functionality and fun of the gyro accelerator 200, and has high marketing value.

Example 4

This embodiment provides a gyro toy, which includes the gyro accelerator 200 as described in Embodiment 2 or 3, and also includes a gyro 300, which is magnetically connected to the adsorption iron plate 52 of the adsorption assembly 50 of the gyro accelerator 200.

Specifically, the top of the top of the gyroscope 300 of this embodiment is provided with an iron disc 301. In this way, the top of the gyroscope 300 of this embodiment can be magnetically attracted to a device with a magnetic attraction function through the iron disc 301 on its top. The bottom of the iron plate 52 can drive the adsorption iron plate 52 and the gyro 300 to rotate and accelerate through the driving device 100, and the gyro 300 after rotation and energy accumulation can be pushed out through the ejection assembly 60.

In order to make the connection between the top 300 and the iron adsorption plate 52 more stable, in this embodiment, an annular first rack 54 is provided at the bottom of the iron adsorption plate 52. The iron disc of the top 300 is 301 is provided with an annular second rack 302, and the first rack 54 of the adsorbing iron plate 52 and the second rack 302 of the gyroscope 300 are engaged with each other. In this way, when the top 300 is magnetically attracted to the adsorption iron plate 52, the second rack 302 of the top 300 just meshes with the first rack 54 of the adsorption iron plate 52, making the two relatively more stable during rotation. Not prone to displacement.

Therefore, the gyro toy of this embodiment drives the gravity ball 40 of the driving device 100 to move in a circular motion by rotating and shaking, and then drives the acceleration gear set 30 to rotate synchronously through the linkage rod 41, and drives the gyro toy by continuously shaking the housing 10. The gravity ball 40 makes a circular motion, causing the gravity ball 40 to rotate faster and faster under the action of inertia. At the same time, the linkage shaft 31 of the acceleration gear set 30 obtains more and more rotational potential energy, and then the linkage shaft 31 drives the adsorption assembly 50 to rotate synchronously. , in this way, the top 300 adsorbed by the adsorption component 50 also obtains a greater rotational potential energy, and can push the stored energy top 300 out through the push component 60, making the top toy of this solution novel and interesting to play. , and is easy to operate, which expands the functionality and fun of gyro toys and has high marketing value.

The above-mentioned embodiments only express several implementation modes of the present solution, and their descriptions are relatively specific and detailed, but should not be construed as limiting the scope of the driving device of the solution. 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 this solution, and these all fall within the protection scope of this solution.

Claims (10)

1. A driving device characterized by:

   It includes a housing, a base and an acceleration gear set. The base is provided in the housing. The acceleration gear set is rotatably provided on the base. A gravity ball is slidably provided on the base. The gravity ball is connected to the acceleration gear set through a linkage rod; when the gravity ball is driven to make a circular motion on the base, the gravity ball drives the acceleration gear set to rotate through the linkage rod.
2. The driving device according to claim 1, characterized in that:

   One end of the linkage rod is fixedly connected to the acceleration gear set, the other end of the linkage rod is provided with a U-shaped clamping opening, and the gravity ball is rotatably arranged in the U-shaped clamping opening of the linkage rod.
3. The driving device according to claim 1, characterized in that:

   The acceleration gear set is rotatably arranged in the middle of the base, and an annular chute is provided on the upper surface of the base with the middle of the base as the center. The radius of the annular chute is the same as the length of the linkage rod. , the gravity ball is slidably arranged in the annular chute, and the gravity ball makes a circular motion with the acceleration gear set as the center.
4. The driving device according to claim 3, characterized in that:

   The acceleration gear set includes a linkage rotating shaft and a driving gear. The linkage rotating shaft is rotatably mounted on the base through a bearing structure, and the linkage rotating shaft is fixedly connected to the linkage rod; the driving gear is coaxially fixed. Set on the linkage shaft.
5. The driving device according to claim 4, characterized in that:

   The acceleration gear set also includes a driven gear, the driven gear is rotatably disposed in the housing, and the driven gear is meshedly connected with the driving gear.
6. The driving device according to claim 5, characterized in that:

   One or more transmission gears are provided between the driving gear and the driven gear, the one or more transmission gears are rotatably provided in the housing, and the driving gear, one or more transmission gears, The driven gears are meshed and connected in sequence.
7. A gyro accelerator, characterized by:

   It includes the driving device according to any one of claims 1 to 6, further comprising an adsorption component for adsorbing the top and a push component for launching the top; the driving device is used to drive the adsorption component Rotatingly, the ejection component is telescopically arranged on the housing.
8. The gyro accelerator according to claim 7, characterized in that:

   The adsorption assembly includes a connecting rod, an adsorption iron plate and an adsorption magnet. The upper end of the connecting rod is coaxially fixedly connected to the acceleration gear set of the driving device, and the lower end of the connecting rod is fixedly connected to the adsorption iron plate. The bottom of the adsorption iron plate is used to adsorb the top, the adsorption magnet is magnetically connected to the adsorption iron plate, and the adsorption magnet is movably set on the connecting rod; the push assembly is used to push the The adsorption magnet pushes away from the adsorption iron plate.
9. The gyro accelerator according to claim 8, characterized in that:

   The pushing assembly includes a push rod, a return spring and a push-off rod. The push rod is telescopically arranged in the housing through the return spring, and one end of the push rod extends out of the housing. , the other end of the push rod is against the upper end side of the push-off rod; the middle part of the push-off rod is rotatably provided in the housing, and the lower end of the push-off rod is provided with a hook, The hooking portion is located below the adsorption magnet; when the push rod is pressed to drive the push-off rod to rotate, the push-off rod drives the adsorption magnet upward through the hooking portion at the bottom and separates from the adsorption iron plate.
10. A spinning top toy, which is characterized by:

    It includes the gyro accelerator according to any one of claims 7 to 9, further comprising a gyroscope, the gyroscope is magnetically connected to the adsorption iron plate.