Top toy

By designing rotatable operating parts and locking tongue structure in the spinning top toy, the attack parts can be easily locked and unlocked, solving the problem that the attack parts of existing spinning top toys cannot be replaced, and enhancing the fun and personalized experience.

WO2026144432A1PCT designated stage Publication Date: 2026-07-09ALPHA GROUP CO LTD +2

Patent Information

Authority / Receiving Office
WO · WO
Patent Type
Applications
Current Assignee / Owner
ALPHA GROUP CO LTD
Filing Date
2025-10-21
Publication Date
2026-07-09

AI Technical Summary

Technical Problem

The attack parts of existing spinning top toys cannot be replaced according to actual needs, which affects the fun of playing and the ability to personalize them.

Method used

Design a spinning top toy that uses an operating component to lock and unlock the attacking component. The operating component can be rotated to different positions to lock or unlock the attacking component, and the locking tongue and latch work together to make it easy to assemble and disassemble.

Benefits of technology

It enables convenient disassembly and replacement of attack components, meeting diverse play needs and enhancing the fun and personalized experience.

✦ Generated by Eureka AI based on patent content.

Smart Images

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    Figure CN2025129105_09072026_PF_FP_ABST
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Abstract

The present application discloses a top toy. The top toy comprises a top body and an attack component. The top body is configured to rotate. The top toy comprises an operating component. The operating component is configured to be controlled by a user to be movable. The attack component is arranged on the top body. The operating component is configured to lock and unlock the attack component during movement. When locked by the operating component, the attack component is configured to be fixed to the top body so as to rotate along with the top body, and when unlocked by the operating component, the attack component is configured to be separated from the top body. By means of the cooperation of an operating component and an attack component, locking and unlocking of the attack component can be achieved, so that different attack components can be conveniently replaced according to actual requirements, thereby improving playing fun and meeting personalized requirements.
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Description

Spinning top toy

[0001] Cross-reference to related applications

[0002] This application claims priority to Chinese Patent Application No. 202423322053.3, filed with the Chinese Patent Office on December 31, 2024, entitled “Spinning Top Toy”, the entire contents of which are incorporated herein by reference. Technical Field

[0003] This application relates to the field of toys, and more particularly to a spinning top toy. Background Technology

[0004] Spinning tops can rotate at high speeds on their supporting surface. In particular, when multiple spinning tops are present in the same area, they collide with each other during high-speed rotation, providing a certain level of competitive enjoyment. Generally, spinning tops have impact parts for collisions, but currently, these impact parts cannot be replaced by the user according to their specific needs.

[0005] Application content

[0006] This application aims to at least partially solve one of the technical problems in the related art. To this end, this application proposes a spinning top toy.

[0007] To achieve the above objectives, this application discloses a spinning top toy, which includes:

[0008] A gyroscope body adapted for rotation, the gyroscope body including an operating component adapted for user control to be movable; and

[0009] An attack component is disposed on the gyroscope body. The operating component is adapted to lock and unlock the attack component during operation. When locked by the operating component, the attack component is fixed to the gyroscope body so as to rotate with the gyroscope body. When unlocked by the operating component, the attack component is adapted to detach from the gyroscope body.

[0010] In some embodiments of this application, the operating component is rotatable relative to the rest of the gyroscope body and is rotatable to a first position and a second position. The operating component is adapted to lock the attack component when rotated to the first position and to unlock the attack component when rotated to the second position.

[0011] In some embodiments of this application, the operating component is provided with a locking tongue, and the attacking component is provided with a locking buckle. The locking tongue is adapted to insert the locking buckle when the operating component is rotated to the first position to stop the locking buckle in the direction in which the attacking component leaves the gyroscope body, and is adapted to disengage the locking buckle when the operating component is rotated to the second position to avoid the locking buckle in the direction in which the attacking component leaves the gyroscope body.

[0012] In some embodiments of this application, the gyroscope body is provided with a slot adapted for insertion of the latch, the latch being adapted to move into the slot to insert the latch when the operating component is rotated to the first position, and adapted to move out of the slot to disengage the latch when the operating component is rotated to the second position.

[0013] In some embodiments of this application, a plurality of slots are provided along the circumference of the gyroscope body, and the number of slots, the latches and the bolts correspond one-to-one.

[0014] In some embodiments of this application, the gyroscope body is provided with a first limiting groove and a second limiting groove that are connected to each other, and the operating component is provided with a limiting claw. The limiting claw is adapted to reciprocate between the first limiting groove and the second limiting groove when the operating component rotates, and is located in the first limiting groove when the operating component rotates to the first position, and is located in the second limiting groove when the operating component rotates to the second position.

[0015] In some embodiments of this application, the gyroscope body is further provided with a contact portion located between the first limiting groove and the second limiting groove. The contact portion is adapted to stop the limiting claw, and at least one of the contact portion and the limiting claw is adapted to elastically deform so that the limiting claw can pass over the contact portion.

[0016] In some embodiments of this application, the operating component is annular and surrounds the rotation axis of the gyroscope body.

[0017] In some embodiments of this application, the operating component includes a first operating member and a second operating member connected to each other, the first operating member having a locking tongue and the second operating member having a limiting claw.

[0018] In some embodiments of this application, one of the first operating member and the second operating member is provided with a slot and the other is provided with a protrusion. The protrusion is adapted to be embedded in the slot along the axial direction of the gyroscope body, and the protrusion and the slot are adapted to abut against each other along the circumferential direction of the gyroscope body.

[0019] In some embodiments of this application, the gyroscope body further includes:

[0020] A support shell, wherein the operating component is rotatably disposed around the support shell;

[0021] The drive gear is connected to the support shell;

[0022] The retaining shell, the structure formed by the surrounding support shell and the drive gear; and

[0023] The bearing is located between the retaining shell, the supporting shell, and the drive gear in the structure formed by their connection.

[0024] In some embodiments of this application, the support shell includes an upper shell and a lower shell connected together, the upper shell and the lower shell clamping the operating component.

[0025] In some embodiments of this application, the support housing and the drive gear clamp the inner side of the bearing.

[0026] In some embodiments of this application, the retaining shell includes an upper retaining ring and a lower retaining ring connected to each other, the upper retaining ring and the lower retaining ring clamping the outer side of the bearing.

[0027] In some embodiments of this application, the spinning top toy further includes a spinning tip, which is snapped together with the spinning top body, and the spinning top body is adapted to be rotatably supported on a support surface via the spinning tip.

[0028] In some embodiments of this application, the projection along the axial direction of the gyroscope toy is such that the projection of the attacking component is larger than the projection of the gyroscope body, and the projection of the gyroscope body is located within the projection range of the attacking component.

[0029] In some embodiments of this application, the attack component includes a first attack component and a second attack component, the second attack component is disposed on the gyroscope body, the first attack component is stacked on top of the second attack component and is adapted to be locked and unlocked by the operating component, so as to be adapted to clamp the second attack component with the gyroscope body.

[0030] In some embodiments of this application, the first attack member and the second attack member are in a ring shape, and the attack member further includes a sandwich member, which is surrounded by the first attack member and the second attack member, and is clamped by the first attack member and the second attack member or by the first attack member and the gyroscope body, and the sandwich member is exposed above the first attack member.

[0031] In some embodiments of this application, the attack component includes a first attack component and a sandwich component. The first attack component is annular and adapted to be locked and unlocked by the operating component. The sandwich component is surrounded by the first attack component and held by the first attack component and the gyroscope body. The sandwich component is exposed above the first attack component.

[0032] In some embodiments of this application, a first attack component is disposed on the gyroscope body; and / or a second attack component is disposed on the gyroscope body.

[0033] Other advantages of this application will be set forth in part in the description which follows, and in part will be obvious from the description or may be learned by practice of this application. Attached Figure Description

[0034] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this application. For those skilled in the art, other designs can be obtained based on the structures shown in these drawings without creative effort.

[0035] Figure 1 is a schematic diagram of a toy gyroscope in some embodiments;

[0036] Figure 2 is an exploded view of the toy gyroscope in some embodiments;

[0037] Figure 3 shows an exploded view of the toy gyroscope in some embodiments (the degree of decomposition is different from that in Figure 2);

[0038] Figure 4 shows an exploded view of the toy spinning top in some embodiments (the degree of decomposition is different from that in Figures 2 and 3);

[0039] Figure 5 is a schematic diagram of the first attack component in some embodiments;

[0040] Figure 6 is a schematic diagram of the gyroscope body in an unlocked state in some embodiments (the operating component is rotated to the second position);

[0041] Figure 7 is a schematic diagram of the gyroscope body in an unlocked state in some embodiments (the viewpoint is different from Figure 6);

[0042] Figure 8 is a schematic diagram of the gyroscope body in a locked state in some embodiments (the operating component is rotated to the first position);

[0043] Figure 9 is a schematic diagram of the gyroscope body in a locked state in some embodiments (the viewpoint is different from Figure 8);

[0044] Figure 10 is a schematic diagram of the operating components in some embodiments;

[0045] Figure 11 is an exploded view of the operating components in some embodiments;

[0046] Figure 12 is a cross-sectional view of a spinning top toy in some embodiments;

[0047] Figure 13 is an exploded view of the gyroscope body in some embodiments;

[0048] Figure 14 is a cross-sectional view of the gyroscope body in some embodiments;

[0049] Figure 15 is a schematic diagram of the upper shell in some embodiments.

[0050] Reference numerals in the attached diagram: Gyroscope body 1000, support shell 1100, upper shell 1110, slot 1111, positioning slot 1112, first limiting slot 1113, second limiting slot 1114, contact part 1115, lower shell 1120, operating part 1200, first operating component 1210, locking tongue 1211, slot 1212, second operating component 1220, limiting claw 1221, locking protrusion 1222, drive gear 1300, retaining shell 1400, upper retaining ring 1410, lower retaining ring 1420, bearing 1500, attacking component 2000, first attacking component 2100, locking buckle 2110, second attacking component 2200, positioning part 2210, interlayer component 2300, gyroscope tip 3000.

[0051] The realization of the purpose, functional features and advantages of this application will be further explained in conjunction with the embodiments and with reference to the accompanying drawings. Detailed Implementation

[0052] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only a part of the embodiments of this application, and not all of the embodiments. Based on the embodiments of this application, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the scope of protection of this application.

[0053] It should be noted that all directional indicators (such as up, down, left, right, front, back, etc.) in the embodiments of this application are only used to explain the relative positional relationship and movement of each component in a certain specific posture (as shown in the figure). If the specific posture changes, the directional indicator will also change accordingly.

[0054] In this application, unless otherwise expressly specified and limited, the terms "connection," "fixed," etc., should be interpreted broadly. For example, "fixed" can mean a fixed connection, a detachable connection, or an integral part; it can mean a mechanical connection or an electrical connection; it can mean a direct connection or an indirect connection through an intermediate medium; it can mean the internal communication of two components or the interaction between two components, unless otherwise expressly limited. Those skilled in the art can understand the specific meaning of the above terms in this application according to the specific circumstances.

[0055] Furthermore, the use of terms such as "first" and "second" in this application is for descriptive purposes only and should not be construed as indicating or implying their relative importance or implicitly specifying the number of technical features indicated. Therefore, a feature defined as "first" or "second" may explicitly or implicitly include at least one of those features. Additionally, the technical solutions of the various embodiments can be combined with each other, but only on the basis of being achievable by those skilled in the art. If the combination of technical solutions is contradictory or impossible to implement, such a combination of technical solutions should be considered non-existent and not within the scope of protection claimed in this application.

[0056] This application discloses a spinning top toy. As shown in Figures 1 to 10, in some embodiments, the spinning top toy includes a spinning top body 1000 and an attack component 2000. The spinning top body 1000 is adapted to rotate and includes an operating component 1200. The operating component 1200 is adapted to be movable and controlled by a user. The attack component 2000 is disposed on the spinning top body 1000. The operating component 1200 is adapted to lock and unlock the attack component 2000 when it is active. When locked by the operating component 1200, the attack component 2000 is adapted to be fixed to the spinning top body 1000 and can rotate with the spinning top body 1000. When unlocked by the operating component 1200, the attack component 2000 is adapted to detach from the spinning top body 1000.

[0057] By cooperating with the attack component 2000, the attack component 2000 can be locked and unlocked, making it convenient to replace the attack component 2000 according to actual needs, which helps to enhance the fun of playing and meet diverse individual needs.

[0058] Specifically, the gyroscope body 1000 can rotate when driven. The gyroscope body 1000 includes an operating component 1200. It can be understood that when the gyroscope body 1000 rotates, the operating component 1200 also rotates. The operating component 1200 is configured to be movable and is for user control. User control means that the user applies force to the operating component 1200, causing it to move accordingly. The movement of the operating component 1200 can lock and unlock the attack component 2000. That is, to lock the attack component 2000, the user needs to control the operating component 1200 to make it move accordingly, thus locking the attack component 2000. To unlock the attack component 2000, the user needs to control the operating component 1200 to make it move accordingly, thus unlocking the attack component 2000.

[0059] When the operating component 1200 locks the attack component 2000, the attack component 2000 is fixed to the spinning top body 1000. Thus, the attack component 2000 rotates along with the spinning top body 1000, allowing the spinning top to collide with other objects (such as other spinning tops, walls, obstacles, etc.). When the operating component 1200 unlocks the attack component 2000, the attack component 2000 and the spinning top body 1000 detach. This allows for the replacement of a new or different attack component 2000 according to play requirements. When reinstalling the new or different attack component 2000 onto the spinning top body 1000, the operating component 1200 can be used to relock the attack component 2000. This design facilitates the removal and replacement of the attack component 2000, especially allowing for the selection of different specifications of the attack component 2000 according to play requirements or user preferences, thus enhancing the enjoyment of the game.

[0060] The movable setting of the operating component 1200 is specifically achieved by rotation, facilitating the locking and unlocking of the attack component 2000 under user control. Referring to Figures 6 to 9, in some embodiments, the operating component 1200 can rotate relative to the rest of the gyroscope body 1000, and can rotate to a first position and a second position. The operating component 1200 is adapted to lock the attack component 2000 when rotated to the first position, and is adapted to unlock the attack component 2000 when rotated to the second position.

[0061] Specifically, in addition to rotating along with the gyroscope body 1000, the operating component 1200 can also rotate relative to the rest of the gyroscope body 1000, including components such as the support shell 1100, drive gear 1300, and retaining shell 1400 mentioned below. When the user controls the operating component 1200, it locks and unlocks the attack component 2000 by rotating. The operating component 1200 can rotate to a first position and a second position. When rotated to the first position, the attack component 2000 is locked; when rotated to the second position, it is unlocked. This design allows the user to manually control the operating component 1200 to disassemble and assemble the attack component 2000 without needing tools, making the process more convenient and faster.

[0062] For example, when the operating component 1200 rotates forward to the first position, it can lock the attack component 2000; when the operating component 1200 rotates backward to the second position, it can unlock the attack component 2000. Alternatively, the operating component 1200 can rotate a certain angle in one direction and reach the first position to lock the attack component 2000; continuing to rotate a certain angle and reaching the second position can unlock the attack component 2000. It is understood that configuring the operating component 1200 to reciprocate between the first and second positions to achieve locking and unlocking of the attack component 2000 would be more conducive to simplifying the structure.

[0063] The operating component 1200 and the attacking component 2000 are locked and unlocked through the cooperation of the locking tongue 1211 and the latch 2110, improving the convenience and stability of disassembly and assembly. Referring to Figures 1 to 12, in some embodiments, the operating component 1200 is provided with a locking tongue 1211, and the attacking component 2000 is provided with a latch 2110. The locking tongue 1211 is adapted to insert the latch 2110 when the operating component 1200 rotates to a first position, so as to stop the latch 2110 in the direction in which the attacking component 2000 disengages from the gyroscope body 1000, and is also adapted to disengage the latch 2110 when the operating component 1200 rotates to a second position, so as to avoid the latch 2110 in the direction in which the attacking component 2000 disengages from the gyroscope body 1000.

[0064] Specifically, the shapes of the locking tongue 1211 and the latch 2110 are not limited. When the operating component 1200 rotates, the locking tongue 1211 moves accordingly, thereby enabling it to engage with the latch 2110. That is, when the operating component 1200 rotates to the first position, the locking tongue 1211 moves to the corresponding position and inserts into the latch 2110. It can be understood that the insertion of the locking tongue 1211 into the latch 2110 means that the locking tongue 1211 and the latch 2110 mutually restrict each other. In this way, the locking tongue 1211 stops the latch 2110 in the direction in which the attacking component 2000 detaches from the gyroscope body 1000. That is, at this time, the operating component 1200 locks the attacking component 2000, and the attacking component 2000 is fixed on the gyroscope body 1000 and will not detach from the gyroscope body 1000. When the operating component 1200 rotates to the second position, the locking tongue 1211 moves to the corresponding position and disengages from the latch 2110. It can be understood that the disengagement of the locking tongue 1211 from the latch 2110 means that the locking tongue 1211 and the latch 2110 are no longer mutually restrictive. Thus, the locking tongue 1211 avoids the latch 2110 in the direction in which the attacking component 2000 disengages from the gyroscope body 1000. That is, at this time, the operating component 1200 unlocks the attacking component 2000, and the attacking component 2000 can disengage relative to the gyroscope body 1000.

[0065] Referring to Figures 3 to 9 and Figure 15, in some embodiments, the gyroscope body 1000 is provided with a slot 1111. The slot 1111 is adapted for inserting the latch 2110. The locking tongue 1211 is adapted to move into the slot 1111 to insert the latch 2110 when the operating member 1200 rotates to a first position, and is adapted to move out of the slot 1111 to disengage the latch 2110 when the operating member 1200 rotates to a second position. When the attack member 2000 is installed onto the gyroscope body 1000, the latch 2110 needs to be inserted into the slot 1111. This serves to position the attack member 2000 during installation, thereby facilitating the engagement of the locking tongue 1211 and the latch 2110.

[0066] Specifically, when the attack component 2000 is installed onto the gyroscope body 1000, the latch 2110 is inserted into the slot 1111. The control operating component 1200 is rotated to the first position, causing the locking tongue 1211 to move into the slot 1111. During the movement of the locking tongue 1211 into the slot 1111, it is inserted into the latch 2110, thus locking the attack component 2000. When the control operating component 1200 is rotated to the second position, the locking tongue 1211 moves out of the slot 1111, disengaging from the latch 2110, thus unlocking the attack component 2000. Based on the gyroscope body 1000 supporting the attack component 2000, the slot 1111 provides clearance for the latch 2110 and the locking tongue 1211, facilitating the cooperation of various components.

[0067] Optionally, multiple slots 1111 are provided along the circumference of the gyroscope body 1000. The number of slots 1111, latches 2110 and locking tongues 1211 correspond one-to-one. Multiple means two or more. By providing multiple slots 1111 in the circumference, the attack component 2000 can be locked in the circumference of the gyroscope body 1000, making the installation of the attack component 2000 more secure.

[0068] As mentioned above, configuring the operating component 1200 to reciprocate between a first position and a second position to lock and unlock the attack component 2000 will be more conducive to simplifying the structure. In order to limit the travel of the reciprocating rotation of the operating component 1200, in conjunction with Figures 6 to 9, in some embodiments, the gyroscope body 1000 is provided with a first limiting groove 1113 and a second limiting groove 1114 that are connected, and the operating component 1200 is provided with a limiting claw 1221. The limiting claw 1221 is adapted to reciprocate between the first limiting groove 1113 and the second limiting groove 1114 when the operating component 1200 rotates, and is located in the first limiting groove 1113 when the operating component 1200 rotates to the first position, and in the second limiting groove 1114 when the operating component 1200 rotates to the second position.

[0069] Specifically, as the operating component 1200 reciprocates, the limiting pawl 1221 can reciprocate between the first limiting groove 1113 and the second limiting groove 1114. When the operating component 1200 rotates to the first position, the limiting pawl 1221 is located in the first limiting groove 1113. If the operating component 1200 rotates from the first position to the second position, the limiting pawl 1221 moves from the first limiting groove 1113 into the second limiting groove 1114. When the operating component 1200 rotates to the second position, the limiting pawl 1221 is located in the second limiting groove 1114. If the operating component 1200 rotates from the second position to the first position, the limiting pawl 1221 moves from the second limiting groove 1114 into the first limiting groove 1113. By setting the first limiting groove 1113 and the second limiting groove 1114, the stroke of the reciprocating rotation of the operating component 1200 is limited, preventing the operating component 1200 from over-rotating.

[0070] Understandably, the gyroscope body 1000 is rotatable, and the operating component 1200 is configured to rotate relative to the rest of the gyroscope body 1000. To prevent the operating component 1200 from accidentally rotating from a first position to a second position while the gyroscope body 1000 is rotating, as shown in Figures 6 to 9, in some embodiments, the gyroscope body 1000 is further provided with a contact portion 1115 located between a first limiting groove 1113 and a second limiting groove 1114. The contact portion 1115 is adapted to stop the limiting claw 1221, and at least one of the contact portion 1115 and the limiting claw 1221 is adapted to elastically deform so that the limiting claw 1221 can pass over the contact portion 1115.

[0071] During the rotation of the gyroscope body 1000, if the operating component 1200 wants to rotate from the first position to the second position, that is, if the limiting claw 1221 wants to move from the first limiting groove 1113 into the second limiting groove 1114, the limiting claw 1221 will come into contact with the contact part 1115 and be stopped by the contact part 1115. The contact part 1115 forms a certain obstruction to the limiting claw 1221, thus preventing the limiting claw 1221 from moving from the first limiting groove 1113 into the second limiting groove 1114 during the rotation of the gyroscope body 1000 and accidentally unlocking the attack component 2000.

[0072] When it is necessary to unlock the attack component 2000, the user controls the operating component 1200 to rotate from the first position to the second position, so that the limiting claw 1221 moves from the first limiting groove 1113 into the second limiting groove 1114. During the process of moving from the first limiting groove 1113 into the second limiting groove 1114, the limiting claw 1221 will come into contact with the contact part 1115 and be stopped by the contact part 1115. The user needs to continue to apply a rotational force to the operating component 1200. The force applied by the user overcomes the stopping effect of the contact part 1115, so that at least one of the limiting claw 1221 and the contact part 1115 undergoes elastic deformation. In this way, the limiting claw 1221 can pass over the contact part 1115 and move from the first limiting groove 1113 into the second limiting groove 1114, thus unlocking the attack component 2000.

[0073] Referring to Figures 1 to 10, in some embodiments, the operating component 1200 is annular and surrounds the rotation axis of the gyroscope body 1000, allowing the user to control the operation component 1200 to rotate along the rotation axis of the gyroscope body 1000, thus facilitating user control. In Figure 2, the operating component 1200 protrudes from the circumference of the gyroscope body 1000, making it easy for the user to reach the operating component 1200 and control its rotation.

[0074] Referring to Figures 6 to 11, the operating component 1200 includes a first operating element 1210 and a second operating element 1220 connected to each other. The first operating element 1210 is provided with a locking tongue 1211, and the second operating element 1220 is provided with a limiting claw 1221. This arrangement facilitates the manufacturing of the operating component 1200. In the figures, the first operating component 1200 is annular, and the second operating component 1200 is also annular. The first operating element 1210 and the second operating element 1220 are stacked along the axial direction of the gyroscope body 1000. Since the operating component 1200 needs to rotate, i.e., the first operating component 1210 and the second operating component 1220 need to rotate, optionally, the first operating component 1210 and the second operating component 1220 are engaged in such a manner that one of the first operating component 1210 and the second operating component 1220 has a slot 1212 and the other has a protrusion 1222. The protrusion 1222 is adapted to be inserted into the slot 1212 along the axial direction of the gyroscope body 1000, and the protrusion 1222 and the slot 1212 are adapted to abut against each other along the circumferential direction of the gyroscope body 1000. Through the engagement of the protrusion 1222 and the slot 1212, controlling the rotation of either the first operating component 1210 or the second operating component 1220 can drive the other to rotate.

[0075] For example, when the second operating member 1220 is rotated, the first operating member 1210 rotates accordingly through the cooperation of the latching protrusion 1222 and the latching groove 1212, thus controlling the engagement of the locking tongue 1211 and the latch 2110. Optionally, the outer peripheral surface of the second operating member 1220 can be patterned to increase friction, making it easier for the user to rotate the second operating member 1220.

[0076] As mentioned above, the operating component 1200 is rotatable relative to the rest of the gyroscope body 1000. The rest of the gyroscope body 1000 will be further described below. Referring to Figures 1 to 4 and Figures 13 and 14, in some embodiments, the gyroscope body 1000 further includes a support shell 1100, a drive gear 1300, a retaining shell 1400, and a bearing 1500. The operating component 1200 is rotatably arranged around the support shell 1100. The drive gear 1300 is connected to the support shell 1100. The retaining shell 1400 surrounds the structure formed by the connection between the support shell 1100 and the drive gear 1300. The bearing 1500 is disposed between the retaining shell 1400 and the structure formed by the connection between the support shell 1100 and the drive gear 1300.

[0077] Specifically, the attack component 2000 can be disposed on the support housing 1100, which may be provided with the aforementioned slot 1111, first limiting groove 1113, second limiting groove 1114, and contact part 1115. The connection between the drive gear 1300 and the support housing 1100 means that the drive gear 1300 and the support housing 1100 are connected and fixed so that they can rotate synchronously. The connection between the drive gear 1300 and the support housing 1100 can be achieved by using screws. The retaining shell 1400 surrounds the structure formed by the connection between the supporting shell 1100 and the drive gear 1300, and the bearing 1500 is located between the retaining shell 1400 and the structure formed by the connection between the supporting shell 1100 and the drive gear 1300. This allows the retaining shell 1400 to rotate relative to the structure formed by the connection between the supporting shell 1100 and the drive gear 1300. For example, when playing, the spinning top can be placed on the launcher. The launcher can fix the retaining shell 1400 to achieve the installation and positioning of the spinning top. Then, by driving the drive gear 1300 to rotate, the supporting shell 1100 can be rotated synchronously. At this time, the spinning top body 1000 is in a rotating state, which also makes the attacking part 2000 rotate synchronously.

[0078] Optionally, referring to Figures 13 and 14, the support shell 1100 includes an upper shell 1110 and a lower shell 1120 connected together. The upper shell 1110 and the lower shell 1120 clamp the operating component 1200. The upper shell 1110 may be provided with the slot 1111, the first limiting groove 1113, the second limiting groove 1114, and the contact part 1115 mentioned above. The clamping here is intended to axially limit the operating component 1200, allowing the operating component 1200 to rotate around the support shell 1100. The upper shell 1110 and the lower shell 1120 can be connected by screws. The arrangement of the upper shell 1110 and the lower shell 1120 facilitates the cooperation between the support shell 1100 and the operating component 1200.

[0079] Optionally, as shown in Figures 13 and 14, the support housing 1100 and the drive gear 1300 clamp the inner side of the bearing 1500, specifically, the lower housing 1120 and the drive gear 1300 clamp the inner side of the bearing 1500. For example, the bearing 1500 is sleeved at the connection between the lower housing 1120 and the drive gear 1300, and is clamped on the inner side by the lower housing 1120 and the drive gear 1300. This clamping is intended to form an axial limit on the bearing 1500, so that the drive gear 1300 and the support housing 1100 can rotate relative to the retaining housing 1400 through the bearing 1500.

[0080] Optionally, as shown in Figures 13 and 14, the retaining shell 1400 includes an upper retaining ring 1410 and a lower retaining ring 1420 connected together. The upper retaining ring 1410 and the lower retaining ring 1420 are connected by screws, and the connection of the upper retaining ring 1410 and the lower retaining ring 1420 clamps the outer side of the bearing 1500. The arrangement of the upper retaining ring 1410 and the lower retaining ring 1420 facilitates the cooperation between the bearing 1500 and the retaining shell 1400. The upper retaining ring 1410 and the lower retaining ring 1420 clamp the outer side of the bearing 1500. This clamping is intended to achieve axial limitation of the bearing 1500, so that the structure formed by the retaining shell 1400, the drive gear 1300 and the support shell 1100 can rotate relative to each other.

[0081] Referring to Figures 1 and 2, in some embodiments, the spinning top toy also includes a spin tip 3000. The spinning top body 1000 is rotatably supported on a support surface via the spin tip 3000. By providing the spin tip 3000, the contact area with the support surface is reduced, which further facilitates the rotation of the spinning top body 1000 on the support surface. Optionally, the spin tip 3000 and the spinning top body 1000 are snap-fitted together (the spin tip 3000 and the drive gear 1300 of the spinning top body 1000 are snap-fitted together), so that the user can disassemble and replace the spin tip 3000 according to the actual situation.

[0082] As shown in Figures 1 and 2, in some embodiments, the projection of the attacking component 2000 along the axis of the spinning top toy is larger than the projection of the spinning top body 1000, and the projection of the spinning top body 1000 is located within the projection range of the attacking component 2000. With this setting, when the spinning top toy is spinning, it is more conducive to collision with other objects through the attacking component 2000, thereby increasing the competitive fun.

[0083] Referring to Figures 1 to 5, in some embodiments, the attack component 2000 includes a first attack component 2100 and a second attack component 2200. The second attack component 2200 is disposed on the gyroscope body 1000, and the first attack component 2100 is stacked on top of the second attack component 2200 and is suitable for being locked and unlocked by the operating component 1200 to clamp the second attack component 2200 with the gyroscope body 1000. The first attack component 2100 and the second attack component 2200 are separate components that cooperate with each other after being installed on the gyroscope body 1000. By designing the first attack component 2100 and the second attack component 2200, it is possible to design more or more complex shapes for the attack component 2000, which is more conducive to manufacturing. It is understood that the attack component 2000 is used to collide with other objects, therefore the first attack component 2100 and the second attack component 2200 need to have high structural strength. For example, the first attack component 2100 and the second attack component 2200 are made of metal materials such as aluminum alloy. When installing the first attack component 2100 and the second attack component 2200 onto the gyroscope body 1000, the second attack component 2200 is installed onto the gyroscope body 1000 first (specifically onto the upper shell 1110), and then the first attack component 2100 is installed onto the gyroscope body 1000 (specifically onto the upper shell 1110). The operating component 1200 locks the first attack component 2100, thus causing the first attack component 2100 and the gyroscope body 1000 to clamp the second attack component 2200. In other words, the operating component 1200 locks the attack component 2000. It can be understood that the operating component 1200 locks the first attack component 2100, meaning that the first attack component 2100 is equipped with the locking buckle 2110 mentioned above.

[0084] Optionally, as shown in Figures 1 to 5, the first attack member 2100 and the second attack member 2200 are in a ring shape. The attack member 2000 also includes a sandwich member 2300. The sandwich member 2300 is surrounded by the first attack member 2100 and the second attack member 2200, and is clamped by the first attack member 2100 and the second attack member 2200 or by the first attack member 2100 and the gyroscope body 1000. The sandwich member 2300 is exposed above the first attack member 2100. By designing the sandwich member 2300, after the attack member 2000 is installed on the gyroscope body 1000, the sandwich member 2300 is exposed, which can meet more personalized needs. For example, the sandwich member 2300 can be transparent or have different printing effects.

[0085] In other embodiments, the second attack member 2200 can be omitted while retaining the first attack member 2100 and the interlayer member 2300. The first attack member 2100 is annular and is suitable for being locked and unlocked by the operating component 1200. The interlayer member 2300 is surrounded by the first attack member 2100 and is clamped by the first attack member 2100 and the gyroscope body 1000. The interlayer member 2300 is exposed above the first attack member 2100. This also achieves the fixation of the interlayer member 2300 and meets diverse personalized needs.

[0086] Referring to Figures 1 to 5 and Figure 12, in some embodiments, the second attack member 2200 is sleeved on the gyroscope body 1000, specifically on the upper shell 1110 of the gyroscope body 1000. This provides radial restraint for the second attack member 2200, facilitating its installation. Optionally, the upper shell 1110 has a positioning groove 1112, and the second attack member 2200 has a positioning part 2210. When the second attack member 2200 is sleeved on the gyroscope body 1000, the positioning part 2210 inserts into the positioning groove 1112. The cooperation between the positioning part 2210 and the positioning groove 1112 also provides circumferential positioning for the second attack member 2200. Since the second attack member 2200 is annular, the positioning part 2210 can be located inside the second attack member 2200, allowing it to be hidden after the second attack member 2200 is installed on the gyroscope body 1000.

[0087] Similarly, in some embodiments, the first attack component 2100 is fitted onto the gyroscope body 1000, specifically onto the upper shell 1110 of the gyroscope body 1000. This provides radial restraint for the first attack component 2100, facilitating its installation. In particular, the first attack component 2100 is provided with a latch 2110, and the upper shell 1110 can be provided with a slot 1111. Thus, when the first attack component 2100 is fitted onto the gyroscope body 1000, the latch 2110 inserts into the slot 1111, and the cooperation between the latch 2110 and the slot 1111 also provides circumferential positioning for the first attack component 2100. Since the first attack component 2100 is annular, the latch 2110 can be located on the inner side of the first attack component 2100, allowing it to be hidden after the first attack component 2100 is installed onto the gyroscope body 1000.

[0088] The above description is merely a preferred embodiment of this application and does not limit the patent scope of this application. Any equivalent structural transformations made based on the concept of this application and the contents of the specification and drawings of this application, or direct / indirect applications in other related technical fields, are included within the patent protection scope of this application.

Claims

1. A spinning top toy, wherein, include: A gyroscope body (1000) adapted to rotate, the gyroscope body (1000) including an operating component (1200) adapted to be movable by a user control; as well as An attack component (2000) is disposed on the gyroscope body (1000). The operating component (1200) is adapted to lock and unlock the attack component (2000) during operation. When locked by the operating component (1200), the attack component (2000) is fixed to the gyroscope body (1000) so as to rotate with the gyroscope body (1000). When unlocked by the operating component (1200), the attack component (2000) is adapted to detach from the gyroscope body (1000).

2. The spinning top toy as described in claim 1, wherein, The operating component (1200) is rotatable relative to the rest of the gyroscope body (1000) and is rotatable to a first position and a second position. The operating component (1200) is adapted to lock the attack component (2000) when rotated to the first position and to unlock the attack component (2000) when rotated to the second position.

3. The spinning top toy as described in claim 2, wherein, The operating component (1200) is provided with a locking tongue (1211), and the attacking component (2000) is provided with a latch (2110). The locking tongue (1211) is adapted to insert the latch (2110) when the operating component (1200) rotates to the first position, so as to stop the latch (2110) in the direction in which the attacking component (2000) disengages from the gyroscope body (1000), and is adapted to disengage the latch (2110) when the operating component (1200) rotates to the second position, so as to avoid the latch (2110) in the direction in which the attacking component (2000) disengages from the gyroscope body (1000).

4. The spinning top toy as described in claim 3, wherein, The gyroscope body (1000) is provided with a slot (1111) adapted for the insertion of the latch (2110), and the latch (1211) adapted to move into the slot (1111) to insert the latch (2110) when the operating member (1200) is rotated to the first position, and adapted to move out of the slot (1111) to disengage the latch (2110) when the operating member (1200) is rotated to the second position.

5. The spinning top toy as described in claim 4, wherein, A plurality of slots (1111) are provided along the circumference of the gyroscope body (1000), and the number of slots (1111), the latch (2110) and the bolt (1211) correspond one-to-one.

6. The spinning top toy as described in any one of claims 2 to 5, wherein, The gyroscope body (1000) is provided with a first limiting groove (1113) and a second limiting groove (1114) that are connected to each other. The operating component (1200) is provided with a limiting claw (1221). The limiting claw (1221) is adapted to reciprocate between the first limiting groove (1113) and the second limiting groove (1114) when the operating component (1200) rotates. When the operating component (1200) rotates to the first position, it is located in the first limiting groove (1113), and when the operating component (1200) rotates to the second position, it is located in the second limiting groove (1114).

7. The spinning top toy as described in claim 6, wherein, The gyroscope body (1000) is further provided with a contact portion (1115) located between the first limiting groove (1113) and the second limiting groove (1114). The contact portion (1115) is adapted to stop the limiting claw (1221), and at least one of the contact portion (1115) and the limiting claw (1221) is adapted to elastically deform so that the limiting claw (1221) can pass over the contact portion (1115).

8. The spinning top toy as described in any one of claims 2 to 7, wherein, The operating component (1200) is annular and surrounds the rotation axis of the gyroscope body (1000).

9. The spinning top toy as described in claim 8, wherein, The operating component (1200) includes a first operating component (1210) and a second operating component (1220) connected to each other. The first operating component (1210) is provided with a locking tongue (1211), and the second operating component (1220) is provided with a limiting claw (1221).

10. The spinning top toy as described in claim 9, wherein, One of the first operating member (1210) and the second operating member (1220) is provided with a slot (1212) and the other is provided with a protrusion (1222). The protrusion (1222) is adapted to be inserted into the slot (1212) along the axial direction of the gyroscope body (1000), and the protrusion (1222) and the slot (1212) are adapted to abut against each other along the circumferential direction of the gyroscope body (1000).

11. The spinning top toy as claimed in any one of claims 8 to 10, wherein, The gyroscope body (1000) also includes: A support shell (1100) is provided, and the operating component (1200) is rotatably disposed around the support shell (1100); The drive gear (1300) is connected to the support housing (1100); The retaining shell (1400), the structure formed by the surrounding support shell (1100) and the drive gear (1300); and A bearing (1500) is disposed between the retaining shell (1400), the supporting shell (1100), and the drive gear (1300) in the structure formed by their connection.

12. The spinning top toy as claimed in claim 11, wherein, The support shell (1100) includes an upper shell (1110) and a lower shell (1120) connected to each other, and the upper shell (1110) and the lower shell (1120) clamp the operating component (1200); And / or, the support housing (1100) and the drive gear (1300) clamp the inner side of the bearing (1500); And / or, the retaining housing (1400) includes an upper retaining ring (1410) and a lower retaining ring (1420) connected to each other, the upper retaining ring (1410) and the lower retaining ring (1420) clamping the outer side of the bearing (1500).

13. The spinning top toy as claimed in any one of claims 1 to 12, wherein, The spinning top toy also includes a spin tip (3000), which is snapped together with the spinning top body (1000). The spinning top body (1000) is adapted to be rotatably supported on a support surface via the spin tip (3000).

14. The spinning top toy as claimed in any one of claims 1 to 13, wherein, Projecting along the axis of the spinning top toy, the projection of the attacking component (2000) is greater than the projection of the spinning top body (1000), and the projection of the spinning top body (1000) is located within the projection range of the attacking component (2000).

15. The spinning top toy as claimed in any one of claims 1 to 14, wherein, The attack component (2000) includes a first attack component (2100) and a second attack component (2200). The second attack component (2200) is disposed on the gyroscope body (1000). The first attack component (2100) is stacked on top of the second attack component (2200) and is adapted to be locked and unlocked by the operation component (1200) to be adapted to clamp the second attack component (2200) with the gyroscope body (1000).

16. The spinning top toy as claimed in claim 15, wherein, The first attack member (2100) and the second attack member (2200) are ring-shaped. The attack member (2000) also includes a sandwich member (2300). The sandwich member (2300) is surrounded by the first attack member (2100) and the second attack member (2200), and is clamped by the first attack member (2100) and the second attack member (2200) or by the first attack member (2100) and the gyroscope body (1000). The sandwich member (2300) is exposed above the first attack member (2100).

17. The spinning top toy as claimed in any one of claims 1 to 16, wherein, The attack component (2000) includes a first attack component (2100) and a sandwich component (2300). The first attack component (2100) is annular and is adapted to be locked and unlocked by the operating component (1200). The sandwich component (2300) is surrounded by the first attack component (2100) and is sandwiched between the first attack component (2100) and the gyroscope body (1000). The sandwich component (2300) is exposed above the first attack component (2100).

18. The spinning top toy as claimed in any one of claims 15 to 17, wherein, The first attack component (2100) is fitted onto the gyroscope body (1000).

19. [Correction 05.11.2025 according to Rule 91] The spinning top toy as claimed in claim 15 or 16, wherein, The second attack component (2200) is fitted onto the gyroscope body (1000).