Gyroscopic toy and device for holding a gyroscopic toy

Abstract

The present application relates to a kind of gyroscopic clamping device and gyro toy, the gyroscopic clamping device includes clamping seat and clamping piece, the clamping seat is provided with clamping cavity, the clamping cavity is the cavity structure of one end opening, the clamping piece is movably arranged on the clamping seat, and at least part of the clamping piece is inserted into the clamping cavity;The gyro is provided with the joint part, and the gyro is inserted into the clamping cavity by the joint part and is matched with the part of the clamping piece inserted into the clamping cavity and is jointed.The gyroscopic clamping device of the present application, by the clamping device of clamping piece, clamping cavity, so that the clamping of gyro is simple, and by triggering clamping piece, the gyro can be quickly separated from clamping piece, improve the playability and play experience of gyro toy.

Description

Technical Field

[0001] This invention relates to the field of toy technology, and in particular to a gyroscope clamping device and a gyroscope toy. Background Technology

[0002] As toys serve as tools for intellectual development and entertainment, people's living standards are constantly improving, and users are increasingly demanding higher quality and more functional toys. Among them, spinning tops, in particular, have attracted a large following thanks to animated films and their unique gameplay.

[0003] Existing spinning top toys consist of a spinning accelerator and a spinning top body. The accelerator has two opposing arc-shaped connectors, and the spinning top body has two corresponding arc-shaped slots. The spinning top body is then inserted into the arc-shaped connectors on the accelerator via these slots. A rack and pinion mechanism accelerates the rotation of the arc-shaped connectors. Removing the rack and pinion simultaneously rotates both the arc-shaped connectors and the spinning top body. After removing the rack, forcefully swinging the accelerator downwards allows the spinning top body to detach from the arc-shaped connectors due to its inertia. However, this interference fit between the accelerator and the spinning top body makes it difficult for the user to detach the spinning top. Insufficient force fails to detach the spinning top from the accelerator, while excessive force can cause the spinning top to swing too fast, creating safety hazards and malfunctions, and reducing the user's enjoyment. Summary of the Invention

[0004] Based on this, the purpose of the present invention is to overcome the shortcomings of the prior art and provide a gyroscope clamping device. The clamping device, which consists of a clamping member and a clamping cavity, makes it easy to clamp the gyroscope, and the gyroscope can be quickly separated from the clamping member by triggering the clamping member, thereby improving the playability and play experience of the gyroscope toy.

[0005] To achieve the above objectives, the technical solution adopted by the present invention is as follows:

[0006] A gyroscope clamping device includes a clamping base and a clamping member. The clamping base has a clamping cavity, which is an open-end cavity structure. The clamping member is movably disposed on the clamping base, and at least a portion of the clamping member extends into the clamping cavity. The gyroscope has a locking portion, through which the gyroscope extends into the clamping cavity and engages with the portion of the clamping member extending into the clamping cavity.

[0007] In one embodiment, the side wall of the clamping seat is provided with a through hole or through groove communicating with the clamping cavity, and the clamping member is rotatably disposed in the through hole or through groove of the clamping seat by means of a torsion spring; the part of the clamping member extending into the clamping cavity is the clamping part, at least a part of the clamping member extends out of the outside of the clamping seat, and the part of the clamping member extending out of the outside of the clamping seat is the force-receiving part.

[0008] In one embodiment, one end of the torsion spring is disposed in the through hole or through groove of the clamping seat, and the other end of the torsion spring is disposed on the clamping member; when the force-receiving part is pressed by an external force, it can drive the clamping member and the clamping part to rotate synchronously, or when the clamping part is pressed by the gyroscope, it can drive the clamping member and the force-receiving part to rotate synchronously.

[0009] In one embodiment, the locking part is a locking protrusion, which is disposed on the upper surface of the gyroscope, and a locking groove is provided on the outer peripheral side of the locking protrusion. The locking groove is an annular groove structure formed by recessing into the locking protrusion.

[0010] In one embodiment, two through holes or through slots are symmetrically provided on the side wall of the clamping seat, and the clamping members are movably disposed in the two through holes or through slots, and the two clamping members are symmetrically arranged at the same height.

[0011] In one embodiment, the clamping portions of the two clamping members have an inclined structure on the side facing the opening of the clamping cavity, and the ends of the two clamping portions extending into the innermost part of the clamping cavity are respectively inclined toward the side wall of the clamping cavity, and the sides of the two clamping portions away from the opening of the clamping cavity are parallel to the top surface of the clamping cavity.

[0012] In one embodiment, a driven gear is coaxially disposed at one end of the clamping seat away from the opening of the clamping cavity.

[0013] Compared with traditional technologies, the advantages of the gyroscope clamping device of the present invention are:

[0014] This application utilizes a clamping device consisting of a clamping member and a clamping cavity, along with a locking protrusion and a locking groove on the gyroscope. This allows the gyroscope to automatically open the clamping part of the clamping member after being inserted into the clamping cavity via the locking protrusion. The locking groove on the locking protrusion then engages with the clamping part on the clamping member, making the clamping between the gyroscope and the clamping device simple, quick, and relatively stable. Furthermore, triggering the force-bearing part on the clamping member causes it to rotate, separating the clamping part from the locking groove on the gyroscope. This allows the gyroscope to quickly separate from the clamping member, improving the playability and experience of the gyroscope toy.

[0015] On the other hand, the present invention also provides a spinning top toy, including a spinning top clamping device as described in any of the above technical solutions, and a shell with an opening at one end, wherein the spinning top clamping device is rotatably disposed in the shell, and the opening orientation of the clamping cavity of the spinning top clamping device is consistent with the opening orientation of the shell.

[0016] In one embodiment, the housing is provided with a trigger and a return spring. The trigger is telescopically disposed in the housing via the return spring, and the trigger is provided with a pressing part and a triggering part. The pressing part extends out of the housing, and the triggering part is disposed on one side of the clamping member. When the pressing part is pressed by an external force, the pressing part drives the trigger to move in the direction of compressing the return spring, so that the triggering part presses against the clamping member and causes the gyroscope to disengage from the part of the clamping member that extends into the clamping cavity.

[0017] In one embodiment, a driving device is provided on the housing, and the driving device is drivenly connected to the gyroscope clamping device.

[0018] To better understand and implement this invention, the following detailed description is provided in conjunction with the accompanying drawings. Attached Figure Description

[0019] Figure 1 This is a schematic diagram of the structure of the gyroscope clamping device of the present invention;

[0020] Figure 2 This is a schematic diagram showing the connection between the gyroscope clamping device, the gyroscope, and the trigger element of the present invention;

[0021] Figure 3 This is a schematic diagram showing the connection between the gyroscope clamping device of the present invention and the gyroscope, trigger element, and driving device;

[0022] Figure 4 This is a schematic diagram of the clamping between the gyroscope clamping device and the gyroscope of the present invention;

[0023] Figure 5 This is a schematic diagram of the detachment process between the gyroscope clamping device and the gyroscope of the present invention;

[0024] Figure 6 This is a schematic diagram of the structure of the spinning top toy of the present invention;

[0025] Figure 7 This is one of the schematic diagrams of the internal structure of the spinning top toy of the present invention;

[0026] Figure 8 This is the second schematic diagram of the internal structure of the spinning top toy of the present invention;

[0027] Figure 9 This is the third schematic diagram of the internal structure of the spinning top toy of the present invention.

[0028] Explanation of reference numerals in the attached drawings: 10. Gyroscope clamping device; 11. Clamping base; 12. Driven gear; 13. Clamping cavity; 14. Clamping element; 15. Clamping part; 16. Torsion spring; 17. Force-receiving part; 18. Rotating groove; 20. Gyroscope; 21. Snap-fit ​​protrusion; 22. Snap-fit ​​groove; 30. Housing; 40. Trigger element; 41. Pressing part; 42. Trigger part; 43. Telescopic spring; 50. Drive device; 51. Drive box; 52. Guide slide rod; 53. Gravity block; 54. Drive rack; 55. Drive gear; 56. Clutch gear; 57. Output gear. Detailed Implementation

[0029] To further illustrate the various embodiments, the present invention provides accompanying drawings. These drawings are part of the disclosure of the present invention, primarily used to illustrate the embodiments, and can be used in conjunction with the relevant descriptions in the specification to explain the operating principles of the embodiments. With reference to these drawings, those skilled in the art should be able to understand other possible implementations and the advantages of the present invention.

[0030] In the description of this invention, it should be understood that the terms "center," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "left," "right," "top," "bottom," "inner," "outer," "axial," "radial," and "circumferential" indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are used only for the convenience of describing this invention and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be understood as limiting this invention.

[0031] Please see Figures 1 to 9 This embodiment provides a gyroscope clamping device 10, including a clamping base 11 and a clamping member 14. The clamping base 11 is provided with a clamping cavity 13, which is a cavity structure with one open end. The clamping member 14 is movably disposed on the clamping base 11, and at least a portion of the clamping member 14 extends into the clamping cavity 13. The gyroscope 20 is provided with a clamping part 15, which extends into the clamping cavity 13 through the snap-fit ​​part and engages with the portion of the clamping member 14 extending into the clamping cavity 13. Thus, this embodiment, through the clamping structure composed of the clamping member 14 and the clamping cavity 13, makes clamping the gyroscope 20 simple, and by triggering the clamping member 14, the gyroscope 20 can be quickly separated from the clamping member 14, improving the playability and experience of the gyroscope 20 toy.

[0032] In this embodiment, the side wall of the clamping seat 11 is provided with a through hole or through groove communicating with the clamping cavity 13. The clamping member 14 is rotatably disposed in the through hole or through groove of the clamping seat 11 by means of a torsion spring 16. The part of the clamping member 14 that extends into the clamping cavity 13 is the clamping part 15, and at least a part of the clamping member 14 extends out of the outside of the clamping seat 11. The part of the clamping member 14 that extends out of the outside of the clamping seat 11 is the force-receiving part 17.

[0033] Optionally, in this embodiment, the snap-fit ​​part of the gyroscope 20 is a snap-fit ​​protrusion 21. The snap-fit ​​protrusion 21 is disposed on the upper surface of the gyroscope 20, and a snap-fit ​​groove 22 is provided on the outer peripheral side of the snap-fit ​​protrusion 21. The snap-fit ​​groove 22 is an annular groove structure formed by recessing into the snap-fit ​​protrusion 21.

[0034] Furthermore, the clamping member 14 is rotatably disposed in the through hole or through groove of the clamping base 11, one end of the torsion spring 16 is disposed in the through hole or through groove of the clamping base 11, and the other end of the torsion spring 16 is disposed on the clamping member 14; when the force-receiving part 17 is pressed by an external force, it can drive the clamping member 14 and the clamping part 15 to rotate synchronously, or, when the clamping part 15 is pressed by the gyroscope 20, it can drive the clamping member 14 and the force-receiving part 17 to rotate synchronously. Thus, in this embodiment, by triggering the force-receiving part 17 of the clamping member 14, the clamping member 14 can be rotated, causing the clamping part 15 to separate from the snap-fit ​​groove 22 of the gyroscope 20, thereby enabling the gyroscope 20 to quickly separate from the clamping member 14, improving the playability and play experience of the gyroscope 20 toy.

[0035] In order to make the engagement between the clamping member 14 and the gyroscope 20 more stable, in this embodiment, two through holes or through slots are symmetrically provided on the side wall of the clamping base 11, and the clamping member 14 is movably disposed in the two through holes or through slots, and the two clamping members 14 are symmetrically arranged at the same height.

[0036] On the other hand, in this embodiment, the clamping part 15 of the two clamping members 14 has an inclined structure on the side facing the opening of the clamping cavity 13, and the two clamping parts 15 are respectively inclined towards the side wall of the clamping cavity 13 at the innermost end, and the side of the two clamping parts 15 away from the opening of the clamping cavity 13 is parallel to the top surface of the clamping cavity 13.

[0037] Therefore, when the locking protrusion 21 of the spinning top 20 is inserted into the clamping cavity 13, the top of the locking protrusion 21 will push open the clamping portions 15 of the two clamping members 14 until the two clamping portions 15 are engaged in the locking groove 22 of the locking protrusion 21, quickly completing the engagement between the spinning top 20 and the clamping cavity 13. When it is necessary to release the spinning top 20, the force-bearing portion 17 on the two clamping members 14 is pressed to make the clamping portions 15 on the two clamping members 14 rotate away from the opening of the clamping cavity 13 and push open the locking groove 22 of the locking protrusion 21 to achieve separation between the two. This allows the spinning top 20 to quickly separate from the clamping members 14, improving the playability and experience of the spinning top 20 toy.

[0038] To prevent relative movement between the gyroscope 20 and the clamping cavity 13 when they are held together, the clamping cavity 13 in this embodiment is a polygonal cylindrical cavity structure. Correspondingly, the snap-fit ​​protrusion 21 of the gyroscope 20 is also a polygonal cylindrical structure, such as a hexagon or octagon. Thus, when the two are combined, the outer wall of the snap-fit ​​protrusion 21 of the gyroscope 20 is nested in the clamping cavity 13, making the connection between the two tight and preventing relative movement.

[0039] Optionally, the clamping seat 11 of this embodiment can be used to drive the gyroscope 20, which is movably clamped in the clamping cavity 13, to rotate. Thus, in some embodiments, a driven gear 12 is coaxially provided at the end of the clamping seat 11 away from the opening of the clamping cavity 13. In this way, the clamping seat 11 can be connected to other driving devices 50 through the driven gear 12, so that the driving device 50 can drive the clamping seat 11 to rotate.

[0040] In addition, in some embodiments, a magnetic protrusion may be provided at the end of the clamping seat 11 away from the opening of the clamping cavity 13. The magnetic protrusion can be attracted to other driving devices 50 so that the driving device 50 can drive the clamping seat 11 to rotate.

[0041] This embodiment also provides a spinning top 20 toy, including a spinning top clamping device 10 as described in any of the above technical solutions, and a housing 30 with an opening at one end. The spinning top clamping device 10 is rotatably disposed in the housing 30, and the opening orientation of the clamping cavity 13 of the spinning top clamping device 10 is consistent with the opening orientation of the housing 30.

[0042] In this embodiment, the housing 30 is provided with a rotating bearing, and the end of the clamping seat 11 away from the opening of the clamping cavity 13 is provided with a rotating protrusion, and the rotating protrusion is provided with a rotating groove 18. In this way, the rotating bearing of this embodiment is sleeved in the rotating groove 18 on the rotating protrusion, so that the gyroscope clamping device 10 is rotatably disposed in the housing 30.

[0043] Optionally, the housing 30 of this embodiment is provided with a trigger 40 and a return spring. The trigger 40 is telescopically disposed in the housing 30 via the return spring, and the trigger 40 is provided with a pressing part 41 and a triggering part 42. The pressing part 41 extends out of the housing 30, and the triggering part 42 is disposed on one side of the clamping member 14. When the pressing part 41 is pressed by an external force, the pressing part 41 drives the trigger 40 to move in the direction of compressing the return spring, so that the triggering part 42 presses against the clamping member 14 and causes the gyroscope 20 to disengage from the portion of the clamping member 14 that extends into the clamping cavity 13.

[0044] In order to enable the triggering part 42 to trigger the force-receiving parts 17 on the two clamping members 14 at the same time, the triggering part 42 in this embodiment has a ring structure and is arranged parallel to the two force-receiving parts 17. In this way, when the triggering part 42 presses down on the two force-receiving parts 17, the triggering part 42 can simultaneously press against the two force-receiving parts 17.

[0045] On the other hand, a drive device 50 is provided in the housing 30 of this embodiment, which is drivenly connected to the gyroscope clamping device 10. Thus, in this embodiment, the drive device 50 can drive the gyroscope clamping device 10 to rotate and accelerate, and then the trigger member 40 presses against the clamping member 14, causing the gyroscope 20 to disengage from the portion of the clamping member 14 that extends into the clamping cavity 13.

[0046] Optionally, in some embodiments, the clamping seat 11 of the gyroscope clamping device 10 is provided with a driven gear 12. The driving device 50 of this embodiment includes a driving box 51, an acceleration gear set, and a gravity block 53. The acceleration gear set is rotatably mounted on the driving box 51 and is drivenly connected to the driven gear 12. The gravity block 53 is slidably mounted on the driving box 51 and is drivenly connected to the acceleration gear set. When the gravity block 53 slides back and forth on the driving box 51, the gravity block 53 drives the acceleration gear set to rotate, thereby driving the driven gear 12 to rotate through the acceleration gear set.

[0047] In this embodiment, the acceleration gear set includes a drive gear 55, a clutch gear 56, and an output gear 57. At least a portion of the drive gear 55 extends outside one side of the drive box 51. The gravity block 53 is provided with a drive rack 54, which is drivenly connected to the portion of the drive gear 55 that extends out of the drive box 51. The clutch gear 56 is slidably disposed in the drive box 51 and is meshed with the drive gear 55. The output gear 57 is disposed on one side of the clutch gear 56 and is drivenly connected to the driven gear 12.

[0048] In addition, the drive box 51 of this embodiment is provided with a guide slide rod 52. Correspondingly, the gravity block 53 of this embodiment is provided with a guide slider, and the guide slider is provided with a sliding hole. In this way, the gravity block 53 is sleeved on the guide slide rod 52 through the sliding hole in the guide slider, so that the gravity block 53 can slide back and forth on the guide slide rod 52.

[0049] Therefore, in this embodiment, by employing an acceleration gear set based on the clutch principle, when the drive rack 54 drives the drive gear 55 to rotate in the forward direction, the drive gear 55 drives the clutch gear 56 to rotate, and the clutch gear 56 slides to a position close to the output gear 57 under the centrifugal force of the drive gear 55 and engages with the output gear 57 to drive the output gear 57 to rotate; when the drive rack 54 drives the drive gear 55 to rotate in the reverse direction, the drive gear 55 drives the clutch gear 56 to rotate, and the clutch gear 56 slides to a position away from the output gear 57 under the centrifugal force of the drive gear 55 and does not contact the output gear 57.

[0050] To further improve the efficiency of the acceleration gear set, in this embodiment, the output gear 57 is symmetrically provided with a clutch gear 56 and a drive gear 55 on both sides. The drive box 51 is symmetrically provided with arc-shaped grooves on both sides of the output gear 57. The two clutch gears 56 are slidably disposed in the two arc-shaped grooves. At least a portion of the two drive gears 55 extends out of the two sides of the drive box 51. The gravity block 53 is symmetrically provided with drive racks 54 on both sides. The two drive racks 54 are meshed with the two drive gears 55 respectively. In this way, when the gravity block 53 slides back and forth on the drive box 51, the two drive racks 54 of the gravity block 53 always drive the two drive gears 55 to rotate. Through the symmetrical design of the two clutch gears 56, when the gravity block 53 slides in one direction, only one drive gear 55 will drive the corresponding clutch gear 56 to mesh with the output gear 57 and drive the output gear 57 to rotate. When the gravity block 53 slides in the opposite direction, the other drive gear 55's corresponding clutch gear 56 meshes with the output gear 57 and drives the output gear 57 to rotate. In other words, the gravity block 53 can drive the output gear 57 in the same direction to accelerate as it slides back and forth, effectively improving the acceleration efficiency of the acceleration gear set.

[0051] When playing with the spinning top 20 toy in this embodiment, first insert the spinning top 20 into the opening end of the housing 30, so that the snap-fit ​​protrusion 21 on the spinning top 20 is inserted into the clamping cavity 13 of the clamping seat 11, so that the snap-fit ​​part of the clamping member 14 engages with the snap-fit ​​groove of the snap-fit ​​protrusion 21, and the spinning top 20 can be movably clamped on the clamping seat 11; then, by swinging the housing 30, the gravity block 53 is swung, so that the gravity block 53 slides back and forth on the guide slide rod 52 of the drive box 51, and then the drive on the gravity block 53 is activated. The rack 54 drives the acceleration gear set to rotate and accelerate, and then drives the driven gear 12 and the clamping seat 11 to rotate and accelerate, and simultaneously drives the gyroscope 20 to accelerate and store energy. After storing energy, the gyroscope 20 can press down the pressing part 41 of the trigger member 40 so that the trigger part 42 of the trigger member 40 presses against the force receiving part 17 of the clamping member 14, thereby driving the locking part of the clamping member 14 to disengage from the locking groove of the locking protrusion 21. At this time, the gyroscope 20 can fall out from the opening end of the shell 30 under its own gravity.

[0052] Compared with the prior art, this embodiment, through the ingenious design of the clamping base 11 and clamping member 14 on the gyroscope clamping device 10, makes the cooperation between the gyroscope 20 and the clamping member 14 on the clamping base 11 simple, and the locking or unlocking operation between the two is convenient, making the clamping and acceleration of the gyroscope 20 easier, and improving the fun and playability of the gyroscope 20 toy; in addition, the present invention can drive the gravity block 53 to slide back and forth on the drive box 51 by swinging the shell 30, and the gravity block 53 can drive the acceleration gear set in one direction during the back and forth sliding process, so that the acceleration gear set can continuously drive the gyroscope clamping device 10 to accelerate and synchronously drive the gyroscope 20 to rotate. Then, the trigger member 40 triggers the clamping member 14 to unlock the gyroscope 20 so that the gyroscope 20 can fall out from the opening end of the shell 30. Thus, the way to drive the gyroscope 20 to accelerate is more novel, interesting, convenient and fun.

[0053] In some other embodiments, the drive device 50 may adopt an electrically driven structure design. For example, the drive device 50 includes a drive motor and a power supply. A drive gear is provided at the output end of the drive motor, and then the drive gear is driven to connect with the driven gear 12 on the clamping seat 11. When the power supply supplies power to the drive motor, the drive motor drives the drive gear to rotate, and then the drive gear drives the driven gear 12 on the clamping seat 11 to rotate and accelerate.

[0054] In other embodiments, the drive device 50 may also be a long rack, with a limiting groove provided in the housing 30 for the long rack to pass through, and at least part of the driven gear 12 on the clamping seat 11 is disposed in the limiting groove. In this way, when the long rack passes through the limiting groove, it can engage with the driven gear 12, so that when the long rack is pulled out from the limiting groove, it can drive the driven gear 12 to rotate, thereby synchronously driving the clamping seat 11 and the gyroscope 20 to rotate and accelerate.

[0055] The embodiments described above are merely examples of several implementations of the present invention, and while the descriptions are relatively specific and detailed, they should not be construed as limiting the scope of the invention's gyroscope clamping device and gyroscope toys. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of the present invention, and these all fall within the protection scope of the present invention.

Claims

1. A gyroscope clamping device, characterized in that: The device includes a clamping base and a clamping member. The clamping base has a clamping cavity, which is an open-end cavity structure. The clamping member is movably mounted on the clamping base, and at least a portion of the clamping member extends into the clamping cavity. The gyroscope has a locking part, through which the gyroscope extends into the clamping cavity and engages with the portion of the clamping member extending into the clamping cavity. A driven gear is coaxially provided at one end of the clamping seat away from the opening of the clamping cavity; The side wall of the clamping seat is provided with a through hole or through groove communicating with the clamping cavity. The clamping member is rotatably disposed in the through hole or through groove of the clamping seat by means of a torsion spring. The part of the clamping member that extends into the clamping cavity is the clamping part, and at least a part of the clamping member extends out of the outside of the clamping seat. The part of the clamping member that extends out of the outside of the clamping seat is the force-bearing part. The latching part is a latching protrusion, which is disposed on the upper surface of the gyroscope, and a latching groove is provided on the outer peripheral side of the latching protrusion. The latching groove is an annular groove structure formed by recessing into the latching protrusion. The clamping cavity is a polygonal columnar cavity structure, and the snap-fit ​​protrusion of the gyroscope is a polygonal columnar structure.

2. The gyroscope clamping device according to claim 1, characterized in that: One end of the torsion spring is disposed in the through hole or through slot of the clamping seat, and the other end of the torsion spring is disposed on the clamping member; when the force-receiving part is pressed by an external force, it can drive the clamping member and the clamping part to rotate synchronously, or when the clamping part is pressed by the gyroscope, it can drive the clamping member and the force-receiving part to rotate synchronously.

3. The gyroscope clamping device according to claim 1, characterized in that: Two through holes or through slots are symmetrically provided on the side wall of the clamping seat, and the clamping members are movably arranged in the two through holes or through slots, and the two clamping members are symmetrically arranged at the same height.

4. The gyroscope clamping device according to claim 3, characterized in that: The clamping portions of the two clamping members have an inclined structure on the side facing the opening of the clamping cavity, and the ends of the two clamping portions extending into the innermost part of the clamping cavity are respectively inclined toward the side wall of the clamping cavity. The sides of the two clamping portions away from the opening of the clamping cavity are parallel to the top surface of the clamping cavity.

5. A spinning top toy, characterized in that: The device includes the gyroscope clamping device as described in any one of claims 1 to 4, and further includes a housing with an opening at one end, the gyroscope clamping device being rotatably disposed in the housing, and the opening orientation of the clamping cavity of the gyroscope clamping device being consistent with the opening orientation of the housing.

6. The spinning top toy according to claim 5, characterized in that: The housing is provided with a trigger and a return spring. The trigger is telescopically disposed in the housing via the return spring. The trigger has a pressing part and a triggering part. The pressing part extends out of the housing, and the triggering part is disposed on one side of the clamping member. When the pressing part is pressed by an external force, the pressing part drives the trigger to move in the direction of compressing the return spring, so that the triggering part presses against the clamping member and causes the gyroscope to disengage from the part of the clamping member that extends into the clamping cavity.

7. The spinning top toy according to claim 6, characterized in that: The housing is provided with a driving device, which is drivenly connected to the gyroscope clamping device.

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