CN210728657U - Spinning top - Google Patents

Abstract

The utility model discloses a top, top have components of a whole that can function independently state and fit state, and top includes the top body and the lower top body, goes up the top body and includes: the device comprises an upper body, an upper gyroscope tip, a first combining part, an ejection piece and a locking assembly; the lower gyroscope includes: the upper gyroscope body jumps away from the lower gyroscope body by popping the upper gyroscope tip and supports rotation when the locking assembly is released; in addition, when the upper gyroscope body can be accelerated through the emitter, the upper gyroscope tip is moved to the retraction position from the extension position and drives the ejection piece to store energy, and the upper gyroscope body can be transmitted to the lower gyroscope body through the emitter so as to be combined with the top of the lower gyroscope body. According to the utility model discloses top, cooperation transmitter uses, goes up the top body and can circulate in "fit state-components of a whole that can function independently state-fit state" unlimited time with lower top body.

Description

Spinning top

Technical Field

The utility model relates to a toy field especially relates to a top.

Background

The common gyro toy has relatively single playing method and rotates on the ground as a whole. Some toy gyros trigger the top to deform during fighting to pop up a fairy doll, however, the top stops rotating after the fairy doll is popped up to lose fighting capacity, and the competitive performance of the game is reduced, so that the participation degree of players is insufficient. Some toy gyros can fix weapons on the top or the peripheral wall, and the change form is few, and consumer's experience is not strong, has reduced the interest of recreation. Although some toy gyros can realize the separation of the upper gyro from the lower gyro, the upper gyro after separation can only realize one-time separation after each round of playing, and the upper gyro after separation can not be superposed on the lower gyro during rotation, so that the interactivity is not strong.

SUMMERY OF THE UTILITY MODEL

The utility model discloses aim at solving one of the technical problem that exists among the prior art at least. Therefore, the utility model provides a spinning top, this spinning top can be switched over between components of a whole that can function independently state and fit state, and can launch out the components of a whole that can function independently, and this components of a whole that can function independently can combine with the transmitter repeatedly with higher speed and combine together with another components of a whole that can function independently again.

According to the utility model, the gyroscope has a split state and a combined state, the gyroscope comprises an upper gyroscope body and a lower gyroscope body, the upper gyroscope body and the lower gyroscope body are mutually independent toy bodies in the split state, the upper gyroscope body is combined on the top of the lower gyroscope body in the combined state, wherein,

the upper mass includes: the upper gyroscope comprises an upper body, an upper gyroscope tip, a first combining part, an ejection piece and a locking assembly, wherein the upper gyroscope tip is telescopically arranged at the bottom of the upper body, the upper gyroscope tip is provided with an extending position and a retracting position, the ejection piece is used for normally driving the upper gyroscope tip to eject towards the extending position, the locking assembly is matched with the upper gyroscope tip to lock the upper gyroscope tip at the retracting position, the locking assembly releases the upper gyroscope tip after being triggered to eject the upper gyroscope tip by the ejection piece, and the first combining part is arranged at the bottom of the upper gyroscope body;

the lower gyro includes: the lower top tip is arranged at the bottom of the lower body to support and rotate, the first combining part and the second combining part of the upper top body are combined when the upper top tip is in a retracted position, and the upper top body jumps away from the lower top body by popping up the upper top tip and supports and rotates when the locking assembly is released;

in addition, the upper gyroscope body can accelerate through the emitter, the upper gyroscope tip is enabled to move from the extending position to the retracting position, the ejector is driven to store energy, and the upper gyroscope body can be emitted to the lower gyroscope body through the emitter to be combined with the top of the lower gyroscope body.

According to the gyroscope provided by the embodiment of the utility model, through the structural arrangement of the upper gyroscope body and the lower gyroscope body, after the upper gyroscope body and the lower gyroscope body are combined into the gyroscope, the gyroscope can be combined with the emitter for infinite times, and the gyroscope is accelerated and emitted by the emitter; in the split state, the upper gyroscope body can be combined with the emitter for infinite times and accelerated and emitted by the emitter; when the gyroscope in the integrated state rotates, the upper gyroscope body can be separated from the lower gyroscope body, the upper gyroscope body pops up from the lower gyroscope body, and the upper gyroscope body and the lower gyroscope body can still keep the rotating state after being separated; the upper gyroscope body can be accelerated by the emitter, the upper gyroscope tip is moved to the retraction position from the extension position and drives the ejection piece to store energy, so that the upper gyroscope body can be ejected to the lower gyroscope body by the emitter and combined with the lower gyroscope body again to form the gyroscope, namely, under the condition that the lower gyroscope body does not stop rotating, the upper gyroscope body can be ejected to the lower gyroscope body by the emitter and combined with the lower gyroscope body to continue rotating, the upper gyroscope body can be ejected from the lower gyroscope body for an unlimited time, and the ejected upper gyroscope body can be combined with the lower gyroscope body for an unlimited time; the upper gyroscope body is transmitted to the lower gyroscope body through the transmitter and combined with the lower gyroscope body under the state that the rotating speed of the lower gyroscope body is lower than that of the upper gyroscope body on the transmitter, the upper gyroscope body can drive the lower gyroscope body to accelerate in the combining moment, the upper gyroscope body can repeatedly accelerate for the lower gyroscope body when being combined repeatedly, and the lower gyroscope body can have the kinetic energy for keeping long-term rotation. When the upper gyroscope and the lower gyroscope are matched with the emitter for use, the upper gyroscope and the lower gyroscope can be circulated for infinite times in a combined state, a split state and a combined state.

In some embodiments, the top of the upper gyro body is provided with a third combining portion, the upper gyro body is multiple, each upper gyro body can be independently combined to the top of the lower gyro body when the corresponding upper gyro tip is in the retracted position, the multiple upper gyro bodies can be sequentially stacked in the up-down direction when the corresponding upper gyro tip is in the retracted position, and the first combining portion of the upper gyro body located above is combined with the third combining portion of the upper gyro body located below.

Specifically, the upper gyroscope body and the lower gyroscope body are both provided with accelerating parts at the tops, and the accelerating parts are used for being combined with the transmitting head of the transmitter.

In some embodiments, the top and bottom of the upper gyroscope body and the top of the lower gyroscope body are provided with combined magnetic members.

In some embodiments, the first coupling portion includes a coupling groove provided at a bottom of the upper mass, from which the upper tip is retracted into the upper mass when in the retracted position, and the second coupling portion includes a coupling boss cooperating with the coupling groove.

In some embodiments, the lower gyro further comprises: top needle, elastic driving spare and trigger subassembly, the top needle is at least one, but at least one in the top needle is flexible activity top needle from top to bottom and has primary importance and second place, at primary importance and second place the activity top needle is relative down the length that the body stretches out is different, elastic driving spare with the activity top needle links to each other with normal drive the activity top needle moves towards primary importance, trigger subassembly drive when triggering the activity top needle moves towards the second place.

Specifically, the trigger assembly includes: the upper gyroscope body is movably arranged on the upper body, the bottom of the combination trigger piece is matched with the movable gyroscope needle, and when the upper gyroscope body is combined to the lower gyroscope body, the upper gyroscope body is pressed on the combination trigger piece in a propping mode, so that the combination trigger piece drives the movable gyroscope needle to move.

Further, the trigger assembly includes: the centrifugal trigger piece is movable along the radial direction of the lower gyroscope body and matched with the movable gyroscope needle, and when the rotating speed of the lower gyroscope body exceeds a set rotating speed, the centrifugal trigger piece pushes the movable gyroscope needle to move.

In some embodiments, the upper mass further comprises: the range extending piece is arranged on the upper body in a vertically sliding mode, the upper gyro tip is arranged on the range extending piece in a vertically sliding mode, and the ejection piece and the locking assembly act on the upper gyro tip.

Specifically, the upper body includes: the upper gyroscope lower shell is provided with a telescopic hole in the center, the stroke extending piece is a stroke extending pipe and is matched in the telescopic hole in a sliding manner, and the upper gyroscope tip is matched in the stroke extending pipe in a sliding manner; and the upper gyroscope shell is covered on the lower gyroscope shell and covers the range extending piece.

Further, the locking assembly includes: the locking disc is rotatably arranged on the upper gyroscope body and arranged around the stroke extending pipe, the locking disc is provided with a locking position, and a locking block clamped at the locking position on the upper gyroscope tip is arranged on the inner wall of the locking disc; the reset elastic piece is connected to the lock disc so as to drive the lock disc to rotate towards a locking position; the unlocking trigger piece is connected with the lock disc and triggers the lock disc to deviate from a locking position so as to release the upper gyroscope point.

In some embodiments, a first mating groove is formed in an inner wall of the telescopic hole, a second mating groove corresponding to the first mating groove is formed in a pipe wall of the extension pipe, a mating block which is mated in the second mating groove is formed in an outer wall of the upper gyroscope tip, and in the locking position, the locking block is located above the first mating groove and clamped below the mating block.

Additional aspects and advantages of the invention will be set forth in the description which follows, or may be learned by practice of the invention.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

fig. 1 is a schematic diagram of a spinning top according to an embodiment in a combined state.

Fig. 2 is a schematic view of the top of the embodiment in a split state.

Figure 3 is a schematic view of the upper gyro of an embodiment with the upper gyro tip in the extended position.

Figure 4 is a schematic view of the upper gyro of an embodiment with the upper gyro tip in a retracted position.

Fig. 5 is a schematic diagram of one direction of the upper gyroscope body of one embodiment when the upper gyroscope shell is hidden.

Fig. 6 is a schematic view of the upper gyroscope body of one embodiment in another direction when the upper gyroscope shell is hidden.

Fig. 7 is an exploded view of the upper shell of the upper gyroscope with the upper gyroscope of one embodiment concealed.

Fig. 8 is a schematic view of a lower gyro of an embodiment.

Fig. 9 is an exploded view of a lower gyro of one embodiment.

Fig. 10 is an assembled structural view of a peg-top and a trigger assembly of the lower gyroscope according to the embodiment.

FIG. 11 is a schematic diagram of a transmitter in combination with a top in one embodiment.

FIG. 12 is a schematic diagram of an embodiment of a transmitter for transmitting a top.

FIG. 13 is a schematic diagram of an embodiment in which a top is exploded when colliding with other tops.

Fig. 14 is a schematic diagram of an embodiment in which the upper gyro is launched by the launcher toward the lower gyro.

Reference numerals:

a top 1000,

An upper gyroscope body 100,

The upper body 1, the upper gyroscope lower shell 11, the boss 111, the combination groove 112, the telescopic hole 113, the first matching groove 114, the first rotation limiting groove 115, the upper gyroscope upper shell 12,

An upper gyroscope tip 2, a matching block 21, a second rotation limiting rib 22,

A first joint part 3,

An ejection piece 4,

The locking assembly 5, a locking block 51, a clamping surface 511, a pushing surface 512, a locking disc 52, an upper locking ring 521, a lower locking ring 522, a connecting rib 523, a reset elastic piece 53, an unlocking trigger piece 54,

A travel extension piece 6, a second matching groove 61, a first rotation limiting rib 62, a second rotation limiting groove 63, a travel limiting block 64,

A third joint part 7,

A lower gyroscope 200,

A lower body 210, a slide rail 211,

A lower gyroscope top 220,

A second connecting portion 230,

A peg-top 240, a first peg-top 241, a second peg-top 242, a stop 243,

An elastic driving member 250,

A trigger component 260, a combined trigger 261, a centrifugal trigger 262, a centripetal elastic element 263,

A transmitter 300, a transmitting head 310,

An accelerating part 400, an accelerating block 401,

A combination convex column a, a combination magnetic part b,

Detailed Description

Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "center", "length", "upper", "lower", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. This may be the case to those of ordinary skill in the art.

A spinning top 1000 according to an embodiment of the present invention is described below with reference to the drawings.

According to the embodiment of the present invention, as shown in fig. 1 and fig. 2, the top 1000 has a split state and a combined state, and the top 1000 includes the upper top body 100 and the lower top body 200. As shown in fig. 3 and 8, in the separated state, the upper gyro body 100 and the lower gyro body 200 are independent toy bodies, that is, the upper gyro body 100 and the lower gyro body 200 can be played as separate toys. In the combined state, as shown in fig. 1, the upper mass 100 is coupled to the top of the lower mass 200, and the upper mass 100 and the lower mass 200 are coupled to form a whole gyroscope 1000, which gyroscope 1000 can also be played. Thus, the player has possession of this piece of top 1000, which is equivalent to having three toys.

As shown in fig. 4 to 7, the upper mass 100 includes: go up body 1, go up top 2, first conjunction portion 3, ejection piece 4 and locking subassembly 5, go up top 2 telescopically establish in the bottom of last body 1, go up top 2 and have an extended position and a retracted position, ejection piece 4 is used for often driving top 2 towards the extended position and pops out, locking subassembly 5 and top 2 cooperation are in order to lock top 2 in the retracted position, locking subassembly 5 releases top 2 after triggering in order to pop out top 2 by ejection piece 4. The bottom of the upper mass 100 is provided with a first coupling portion 3.

That is, the top tip 2 of the upper gyro body 100, i.e., the upper gyro tip 2, is reciprocally retractable, the upper gyro body 100 has one shape when the upper gyro tip 2 is in the retracted position, the upper gyro body 100 has another shape when the upper gyro tip 2 is in the extended position, and the upper gyro body 100 can be largely deformed or slightly changed by retracting the gyro tip when playing. The ejection piece 4 drives the upper gyro tip 2 to eject towards the extending position, the upper gyro tip 2 can be locked by the locking component 5 when being located at the retracting position, and the ejection piece 4 is in an energy storage state; when the locking assembly 5 is unlocked, the upper peg 2 is driven to the extended position by the ejector 4, and the ejector 4 is in the energy release state.

When the locking assembly 5 is unlocked, the upper tip 2 can be ejected by the ejector 4. If the upper rotor 100 is on the ground or on other toys such as the lower rotor 200, the upper rotor tip 2 will pop up and push against the ground or other toys such as the lower rotor 200, and the ground or the toys will apply a reaction force to the upper rotor 100, so that the upper rotor 100 will be bounced up as a whole, and the phenomenon of catapulting will occur.

As shown in fig. 8 to 10, the lower gyro 200 includes: a lower body 210, a lower tip 220 and a second coupling portion 230, wherein the lower tip 220 is disposed at the bottom of the lower body 210 for supporting rotation, the first coupling portion 3 and the second coupling portion 230 of the upper mass 100 are coupled when the upper tip 2 is in the retracted position, and the upper mass 100 jumps away from the lower mass 200 by ejecting the upper tip 2 and supports rotation when the locking assembly 5 is released.

In the separated state, the upper gyro body 100 is supported by the upper gyro tip 2 for rotation, and the lower gyro body 200 is supported by the lower gyro tip 220 for rotation. In the combined state, the upper gyro body 100 and the lower gyro body 200 are combined into one integrated gyro 1000, and the entire gyro 1000 is supported for rotation by the lower gyro tip 220. If the top 1000 splits during rotation, the lower top body 200 can remain rotating, and the ejected upper top body 100 can also rotate supported by the protruding upper top tip 2. It should be noted that the extending direction of the upper tip 2 relative to the upper mass 100 is not particularly limited, and the upper tip 2 can extend and contract along the direction of the rotation axis of the upper mass 100, and the extending and contracting direction of the upper tip 2 can form a small angle with the rotation axis. When the upper tip 2 extends and contracts in the up-down direction, the upper mass 100 springs up relative to the lower mass 200 when the upper mass is separated. Since the lower gyro 200 is still rotated when the upper gyro is separated from the lower gyro 200, and the position of the lower gyro 200 is changed during rotation, the sprung upper gyro 100 may not hit the lower gyro 200 when falling, and the upper gyro 100 may be rotated after falling.

In addition, the upper mass 100 can be accelerated by the launcher 300 while moving the upper tip 2 from the extended position to the retracted position and driving the ejector 4 to accumulate energy, and the upper mass 100 can be launched onto the lower mass 200 by the launcher 300 to be combined on top of the lower mass 200.

Thus, according to the gyro 1000 of the embodiment of the present invention, by such a structural arrangement of the upper gyro body 100 and the lower gyro body 200, when the two are combined into the gyro 1000, the gyro 1000 can be combined with the transmitter 300 indefinitely, accelerated and transmitted by the transmitter 300; in the splitting state, the upper gyro 100 can be combined with the launcher 300 indefinitely, accelerated and launched by the launcher 300; when the gyroscope 1000 in the integrated state rotates, the upper gyroscope body 100 can be separated from the lower gyroscope body 200, the upper gyroscope body 100 is ejected from the lower gyroscope body 200, and the upper gyroscope body 100 and the lower gyroscope body 200 can still keep the rotating state after being separated; because the upper gyroscope body 100 can be accelerated by the emitter 300, and simultaneously, the upper gyroscope tip 2 moves from the extending position to the retracting position and drives the ejection piece 4 to store energy, when the lower gyroscope body 200 rotates on the ground, the upper gyroscope body 100 can be emitted onto the lower gyroscope body 200 by the emitter 300 and combined with the lower gyroscope body 200 again to form the gyroscope 1000, namely, under the condition that the lower gyroscope body 200 does not stop rotating, the upper gyroscope body 100 can be emitted onto the lower gyroscope body 200 by the emitter 300 and combined with the lower gyroscope body 200 to continue rotating, so that the upper gyroscope body 100 can be ejected from the lower gyroscope body 200 for infinite times, and the ejected upper gyroscope body 100 can also be combined with the lower gyroscope body 200 for infinite times; under the circumstances that the lower top body 200 does not stall, go up top body 100 and can accelerate and launch to the lower top body 200 through transmitter 300, when the transmitter 300 with last top body 100 acceleratees to the rotational speed and surpasss lower top body 200, combine in the twinkling of an eye top body 100 can drive down top body 200 and accelerate, give down top body 200 back with higher speed, go up top body 100 and can break away from on the top body 200 under following, after the top body 200 rotational speed comes down again slowly, can give top body 100 again through transmitter 300 and accelerate, then superpose again on top body 200 down, so go up top body 100 and can combine repeatedly in order to give down top body 200 and accelerate repeatedly, make the top body 200 can have the kinetic energy that keeps long-term rotation down. When the transmitter 300 is used, the upper rotor 100 and the lower rotor 200 can be cycled in the "combined state-separated state-combined state" for infinite times.

In some embodiments, as shown in fig. 5-7, the upper mass 100 further comprises: the range extending piece 6 is arranged on the upper body 1 in a vertically sliding mode, the upper gyro tip 2 is arranged on the range extending piece 6 in a vertically sliding mode, and the ejection piece 4 and the locking component 5 act on the upper gyro tip 2. The arrangement of the stroke extending member 6 increases the range of the overall size change of the upper gyro body 100 in the extending and retracting direction of the upper gyro tip 2 when the upper gyro tip 2 extends and retracts. Therefore, on the premise that the whole telescopic amplitude is the same, the height of the upper gyro tip 2 can be reduced by arranging the extension piece 6, and the upper gyro tip 2 cannot occupy too high size even if retracted, so that the whole size of the upper gyro body 100 is favorably reduced. Meanwhile, the range extending piece 6 enables the overall visual effect of the upper gyroscope 100 in the extending state and the retracting state of the upper gyroscope tip 2 to be greatly different, and can provide more visual surprises for players.

Specifically, as shown in fig. 7, the upper body 1 is provided with a telescopic hole 113, the telescopic hole 113 penetrates the upper body 1 downward, the stroke extension piece 6 is a stroke extension tube and is slidably fitted in the telescopic hole 113, and the upper gyroscope tip 2 is slidably fitted in the stroke extension tube. The setting of the stroke-extending pipe not only enables the stroke-extending piece 6 to stretch out and draw back along the pipe length direction, but also enables the upper gyro point 2 to stretch out and draw back along the pipe length direction, and double limits of the stroke-extending pipe and the upper gyro point 2 are realized. And cooperate in the journey pipe of extending upper peg-top 2 slidable, spacing between the two realizes easily, is difficult for dropping from the journey pipe of extending when making upper peg-top 2 stretch out, and at least part contracts to in the journey pipe when upper peg-top 2 contracts back, reduces and occupies the volume.

Further, as shown in fig. 7 and 6, a first fitting groove 114 is formed on an inner wall of the telescopic hole 113, a second fitting groove 61 corresponding to the first fitting groove 114 is formed on a pipe wall of the extension pipe, a fitting block 21 fitted in the second fitting groove 61 is formed on an outer wall of the upper gyroscope tip 2, and a part of the locking assembly 5 is located above the first fitting groove 114 and is clamped below the fitting block 21. The first engagement groove 114 defines a locking position of the locking assembly 5, for example, the portion of the locking assembly 5 is the locking block 51, the locking block 51 is located in the locking position when facing the first engagement groove 114, and the locking block 51 is located in the unlocking position when deviating from the first engagement groove 114. The second matching groove 61 is arranged corresponding to the first matching groove 114, on one hand, the matching block 21 only slides along the extending direction of the first matching groove 114, the rotation of the stroke extending pipe and the upper gyro tip 2 is limited, and on the other hand, the matching block 21 can be matched with the locking block 51 when the upper gyro tip 2 retracts.

Alternatively, as shown in fig. 7 and 6, one of the inner wall of the telescopic hole 113 and the travel pipe is provided with a first rotation limiting groove 115, and the other of the inner wall of the telescopic hole 113 and the travel pipe is provided with a first rotation limiting rib 62. This arrangement limits the rotation of the extension tube relative to the upper body 1. One of the distance-extending pipe and the upper gyro tip 2 is provided with a second rotation-limiting groove 63, and the other of the distance-extending pipe and the upper gyro tip 2 is provided with a second rotation-limiting rib 22. This arrangement limits the rotation of the upper tip 2 with respect to the travel tube.

Further optionally, as shown in fig. 7 and 6, a plurality of first rotation limiting grooves 115 are formed in the inner wall of the telescopic hole 113, a plurality of first rotation limiting ribs 62 are correspondingly formed on the tube wall of the stroke extending tube, and the upper ends of at least two first rotation limiting ribs 62 are connected with a stroke limiting block 64. By means of the arrangement, the upper gyroscope tip 2 can be prevented from being separated from the range extending pipe when the upper gyroscope tip 2 is ejected by the ejection piece 4.

In some embodiments, as shown in fig. 5 and 7, the locking assembly 5 comprises: a lock block 51 and a return elastic piece 53, wherein the lock block 51 is movably arranged on the upper body 1 and has a locking position, and the lock block 51 has a clamping surface 511 and a pushing surface 512. The return elastic member 53 is used to constantly drive the lock block 51 toward the locking position. When the upper tip 2 is in the retracted position, the stop surface 511 of the locking piece 51 engages with the upper tip 2 to lock the upper tip 2, the locking piece 51 leaves the locked position after the locking assembly 5 is triggered, and the upper tip 2 is compressed and pushes the locking piece 51 to leave the locked position through the pushing surface 512, so that the upper tip 2 is locked by the reset locking piece 51 after returning to the retracted position.

The upper tip 2 has a fitting block 21, the fitting block 21 is used for fitting with the locking block 51, for example, and the fitting block 21 moves along with the upper tip 2 when it extends and contracts. When the locking piece 51 is in the locking position, the cooperating piece 21 is disposed adjacent to the blocking surface 511 when the upper peg tip 2 is in the retracted position, and the cooperating piece 21 is disposed adjacent to the pushing surface 512 when the upper peg tip 2 is in the extended position. The engaging surface 511 and the pushing surface 512 are designed so that the engaging piece 21 cannot push the lock piece 51 to move when pressing the engaging surface 511, and the engaging piece 21 can push the lock piece 51 to move away from the locked position when pressing the pushing surface 512. Due to the arrangement of the reset elastic piece 53, after the locking block 51 is separated from the unlocking position under the action of external force, when the external force is weakened or disappears, the reset elastic piece 53 can enable the locking block 51 to be quickly restored to the locking position. The locking assembly 5 with the structure utilizes the locking block 51 to block the upper gyroscope tine 2, the locking block 51 is not easy to break, the locking is very reliable, the resetting of the locking assembly 5 is reliable by arranging the resetting elastic piece 53, the locking assembly 5 can be locked and unlocked for infinite times, and the service life of the upper gyroscope 100 can be ensured.

There are various movable forms of the locking block 51, and there are also various corresponding ways of cooperating the upper peg 2 with the locking block 51. For example, with reference to the rotation axis of the gyroscope 100, the locking block 51 may be slidably disposed on the upper body 1 in the radial direction, the locking block 51 may also be slidably disposed on the upper body 1 in the tangential direction, and some of the locking blocks 51 may also be movable around the rotation axis. The part of the upper peg-top 2 that cooperates with the locking block 51 may be a cooperating block 21 as described above, the cooperating hole of the upper peg-top 2 cooperating with the locking block 51 when the locking block 51 is slidable in the radial direction.

The elastic restoring member 53 may be a spring or an elastic rib, and the like, which is not limited herein.

Of course, the structure of the locking assembly 5 is not limited to the locking block 51 and the elastic return element 53. For example, the elastic restoring element 53 may be replaced by two magnetic elements, specifically, one magnetic element is disposed on the locking element 51, and the other magnetic element is disposed on the upper body 1, so that the locking element 51 can be kept at the locking position under the action of magnetic force, the locking element 51 can be moved away from the locking position under the pushing of the upper top 2 or other external force, and when the external force is weakened or the magnetic force disappears, the locking element 51 can be pushed to return to the locking position.

In some embodiments, as shown in fig. 6 and 7, the locking assembly 5 includes: the lock plate 52, the lock plate 52 is rotatably arranged on the upper gyroscope body 100, the lock plate 52 is arranged around the range tube, the lock plate 52 has a locking position, a lock block 51 used for being clamped on the upper gyroscope point 2 in the locking position is arranged on the inner wall of the lock plate 52, and the reset elastic piece 53 is connected to the lock plate 52 so as to drive the lock plate 52 to rotate towards the locking position.

Specifically, as shown in fig. 7, the lock collar 52 includes: an upper locking ring 521, a lower locking ring 522 and at least one tie bar 523, the upper locking ring 521 being arranged around the rotation axis of the upper gyroscope 100, the locking piece 51 being arranged on the upper locking ring 521. The lower locking ring 522 is fitted around the outside of the upper body 1 to be rotated when being collided, the link bar 523 is connected between the upper locking ring 521 and the lower locking ring 522, and the return elastic members 53 are connected to both sides of the link bar 523 in the rotating direction, respectively. Thus, an external force acts on the lower locking ring 522, which force, whether clockwise or anticlockwise with respect to the locking disc 52, moves the locking piece 51 from the locking position, unlocking the upper tumbler 2 and ejecting it. By the arrangement, the upper body 1 has more chances of generating ejection phenomena and is stronger in playability.

In particular, the locking assembly 5 also comprises an unlocking trigger 54, the unlocking trigger 54 being associated with the locking plate 52, the unlocking trigger 54 being such as to trigger the deviation of the locking plate 52 from the locking position in order to release the upper tumbler 2.

Alternatively, the unlocking trigger 54 protrudes outward from the lower lock ring 522, so that when the upper body 1 collides with another toy or an obstacle, the collision force is easily applied to the unlocking trigger 54, rotating the entire lock disk 52. Optionally, the unlocking trigger 54 is plural, and the plural unlocking triggers 54 are provided on the lower lock ring 522 at intervals in the circumferential direction.

In the specific example shown in fig. 7 and 6, when the upper tip 2 is in the retracted position, the lock block 51 is located above the first engagement groove 114 and is clamped below the engagement block 21, the upper surface of the lock block 51 constituting a clamping surface 511, the clamping surface 511 being a plane perpendicular to the axis of rotation of the upper mass 100. The lower surface of the lock piece 51 forms a pushing surface 512, the pushing surface 512 forms an inclined plane or a spiral surface inclined with respect to the rotation axis, and when the engaging piece 21 is pressed against the pushing surface 512 from below, a horizontal component force is generated on the pushing surface 512, so that the lock disc 52 is rotated.

Specifically, as shown in fig. 4, the upper body 1 includes: go up top inferior valve 11 and top epitheca 12, the center of going up top inferior valve 11 forms telescopic hole 113, and extension piece 6 is for extending the journey pipe and cooperate in telescopic hole 113 slidable, goes up top point 2 cooperation slidable in extending the journey pipe, goes up top epitheca 12 lid and covers extension piece 6 on top inferior valve 11. The arrangement is convenient to assemble, so that the stroke-extending pipe and the upper gyro tip 2 are not easy to be separated from the upper body 1 from the upper side of the upper body 1.

Alternatively, as shown in fig. 5 and 7, a portion of the upper-lower gyro housing 11 is recessed upward, the portion of the upper-lower gyro housing 11 recessed upward forms a boss 111 at the top of the upper-lower gyro housing 11, and the bottom of the upper-lower gyro housing 11 is recessed upward forms a coupling groove 112. The provision of the coupling recess 112 allows the upper mass 100 to be coupled to other toys, and in particular, when the upper tip 2 is in the retracted position, the upper mass 100 is more easily coupled to the tops of other toys through the coupling recess 112.

In some embodiments, when the upper peg-top 2 is located at the retraction position, the bottom of the upper peg-top 2 is still located in the combining groove 112, when the top of the lower peg-top 200 has the combining convex pillar a and the combining convex pillar a has a concave hole, the upper peg-top 100 can just cover the lower peg-top 200, the combining groove 112 is matched on the combining convex pillar a, and the retracted upper peg-top 2 is matched on the concave hole.

Further alternatively, the upper locking ring 521 is located between the upper shell 12 and the boss 111, the center of the boss 111 forming a central hole (i.e. the telescopic hole 113 above) where the upper peg-top 2 fits. The boss 111 is arranged, so that a good limiting effect can be achieved on the lock disc 52, the lock disc 52 is guaranteed to rotate around the boss 111 all the time when stressed, and the lock disc 52 is prevented from being dislocated and clamped.

In some embodiments, as shown in fig. 8-10, the lower mass 200 further comprises: top needle 240, elastic driving piece 250 and trigger subassembly 260, top needle 240 is at least one, but in the top needle 240 at least one for the flexible activity top needle of telescopic from top to bottom and have first position and second position, the length that body 210 stretches out under first position and second position activity top needle are relative is different, elastic driving piece 250 links to each other with the activity top needle of activity with the activity top needle activity of normal drive activity top needle orientation first position, trigger subassembly 260 drive activity top needle orientation second position activity when triggering.

When the peg-top needle 240 is a fixed peg-top needle, the bottom of the peg-top needle 240 protrudes from the bottom of the lower peg-top tip 220 to support the lower peg-top body 200 to rotate. When the peg-top needle 240 is a movable peg-top needle, the bottom of the movable peg-top needle can extend into or out of the bottom of the lower peg-top tip 220, the bottom of the movable peg-top needle can also be always located below the bottom of the lower peg-top tip 220, and the movement of the movable peg-top needle changes the extending length of the movable peg-top needle relative to the lower peg-top tip 220.

In some embodiments, the peg-up needle 240 is only one and is a movable peg-up needle. In some embodiments, there are two tourbillons 240, both tourbillons 240 may be movable tourbillons, and one of the two tourbillons 240 may be a fixed tourbillon and the other may be a movable tourbillon. When there are two gyro needles 240, the lower gyro body 200 may be switchably supported and rotated by the two gyro needles 240, and the lower gyro body 200 may also be switchably supported and rotated by the two gyro needles 240 and the bottom of the lower gyro tip 220.

Whether the pins 240 are one or two, all the pins 240 are switched between the first position and the second position by the cooperation of the elastic driving member 250 and the triggering assembly 260, and there may be a third position, a fourth position, etc. in some examples, which are all switched between two positions. The length of the movable peg-top in the two positions extending out of the lower body 210 is different, and the height of the center of gravity of the lower peg-top 200 is different.

In some embodiments, the extension or retraction of the movable peg-top needle changes the rotation state of the lower peg-top body 200. For example, when the lower gyroscope 200 is relatively thin and the gyroscope needle 240 contacting the ground is relatively thin, the rotation axis of the lower gyroscope 200 does not deflect greatly, so that the lower gyroscope 200 can rotate more stably, and the lower gyroscope 200 is of a defense type; when the lower gyroscope 200 is cylindrical, the contact point between the lower gyroscope 200 and the ground is constantly changed, and the rotation axis changes and deflects greatly, so that the lower gyroscope 200 is in a wandering state in the rotation process, and belongs to an attack type.

For convenience of understanding, two gyro needles 240 are taken as an example hereinafter, the two gyro needles 240 are respectively a first gyro needle 241 and a second gyro needle 242, the first gyro needle 241 is a fixed gyro needle, and the second gyro needle 242 is a movable gyro needle. The utility model discloses in by the explanation below, also can deduce the lower top body 200 structure and the trigger mode when first top needle 241 is the activity top needle, second top needle 242 is fixed top needle, therefore this kind of condition is no longer repeated.

The second peg-top needle 242 is formed as a sleeve, to which the first peg-top needle 241 is fixed, from which the first peg-top needle 241 can protrude. Of course, the shape of the second peg-top needle 242 is not limited to a sleeve, for example, the second peg-top needle 242 may be formed in a cylindrical shape and be a plurality of, and the plurality of second peg-top needles 242 are spaced around the first peg-top needle 241.

It should be noted that the first position and the second position are two upper and lower extreme positions of the second gyroscope needle 242 moving in the lower gyroscope body 200, one of the first position and the second position is the highest position of the second gyroscope needle 242, and the other of the first position and the second position is the lowest position of the second gyroscope needle 242. For simplicity, the following description will be made with the first position being the lowest position and the second position being the highest position. Of course, in the embodiment of the present invention, there is also a case where the first position is the highest position and the second position is the lowest position, in which case the assembly relationship of the second peg-top 242 can be directly derived from the assembly relationship of the former case, and therefore the assembly and movement principle in this case will not be described in detail.

In some embodiments, as shown in fig. 9 and 10, the trigger component 260 includes: the upper body 100 is pressed against the combining trigger 261 when the upper body 100 is combined to the lower body 200, so that the combining trigger 261 drives the movable gyro needle to move. When the upper gyro 100 is coupled to the lower gyro 200 in this way, the height of the lower gyro 200 changes from that when the lower gyro is separated from the upper gyro in the coupled state, and the top produces a visual effect that the height of the upper gyro is reduced or increased when the upper gyro is coupled to the lower gyro, and thus the top is more enjoyable and exciting.

Specifically, a trigger hole is formed in the top wall of the lower body 210, the coupling trigger 261 is a rod-shaped member that is slidable up and down, and the upper end of the coupling trigger 261 is fitted into the trigger hole, and even when not triggered, the upper end of the coupling trigger 261 may protrude from the trigger hole.

Further, as shown in fig. 9 and 10, the trigger assembly 260 includes: the centrifugal trigger 262 is movable along the radial direction of the lower gyroscope 200, the centrifugal trigger 262 is matched with the movable gyroscope needle, and the centrifugal trigger 262 pushes the movable gyroscope needle to move when the rotating speed of the lower gyroscope 200 exceeds the set rotating speed. That is, when the rotation speed of the lower gyroscope body 200 exceeds a certain value, the centrifugal trigger 262 slides in a direction away from the rotation axis of the lower gyroscope body 200 due to the centrifugal force, and at this time, the centrifugal trigger 262 can push the movable gyroscope needle to move.

Specifically, the movable peg-top needle is provided with a stop 243, and the trigger assembly 260 acts on the stop 243, so that the movable peg-top needle is easily stressed. More specifically, there are two stops 243, two stops 243 are provided on opposite sides of the movable peg, and as shown in fig. 10, the two stops 243 are arranged at an interval of 180 degrees, and a coupling trigger 261 and a centrifugal trigger 262 act on each stop 243.

Specifically, as shown in fig. 9 and 10, the stopper 243 is provided on the peripheral wall of the second gyro needle 242. The lower gyroscope body 200 is provided with a slide rail 211, the centrifugal trigger 262 slides along the slide rail 211, when the centrifugal trigger 262 slides in a direction away from the rotation axis of the lower gyroscope body 200, the centrifugal trigger 262 pushes the second gyroscope needle 242 to move towards the lowest position, and the elastic driving element 250 is connected between the lower gyroscope tip 220 and the second gyroscope needle 242 to drive the second gyroscope needle 242 to move towards the highest position.

The position of the second peg-top 242 is determined by the dual action of the eccentric triggering member 262 and the elastic driving member 250. When the centrifugal trigger 262 slides away from the rotation axis, the centrifugal trigger 262 is activated, and the centrifugal trigger 262 pushes the second peg-top needle 242 to move towards the lowest position, at which time the second peg-top needle 242 can reach the first position. When the centrifugal trigger 262 slides in the direction of the rotation axis, the centrifugal trigger 262 is deactivated, and the elastic drive element 250, if activated, drives the second peg-top needle 242 towards the uppermost position, at which point the second peg-top needle 242 can reach the second position.

Since the movement of the centrifugal trigger 262 is limited by the sliding rail 211 to slide, the centrifugal trigger 262 moves smoothly when rotating. The centrifugal trigger 262 presses the stop 243 only when sliding relative to the second peg 242, so that the pressing force of the smoothly moving centrifugal trigger 262 on the stop 243 is also smooth, and the second peg 242 is also very smooth when being extended or retracted.

Alternatively, the elastic driving member 250 is a spring fitted over the peg-top needle 240, the elastic driving member 250 may be fitted over the movable peg-top needle, and the elastic driving member 250 may also be fitted over the fixed peg-top needle.

Advantageously, as shown in fig. 10, the triggering assembly 260 also comprises a centripetal elastic element 263 for pushing said centrifugal triggering element 262 active towards the direction of the rotation axis. Optionally, the centering spring 263 is a spring.

In other embodiments of the present invention, the trigger assembly 260 may include an engagement trigger 261 without including the centrifugal trigger 262, and the trigger assembly 260 may include the centrifugal trigger 262 without including the engagement trigger 261. In some embodiments, the triggering assembly 260 can also be triggered by an impact, for example by providing a triggering member on the side wall of the lower mass 200, which presses or lifts the movable peg-top needle when the triggering member is impacted. In some embodiments, the triggering assembly 260 may also be triggered electrically, for example, the triggering member is configured as an electrically controlled valve, etc., and the movement of the valve core is used to trigger the movement of the movable gyro needle.

In other embodiments of the present invention, the lower gyroscope body 200 may also be provided without a movable gyroscope needle, and the center of gravity of the lower gyroscope body 200 is not changed when the lower gyroscope body is combined or collided. In other embodiments, the lower gyro 200 may be provided with a deformation member, which is deployed to deform the lower gyro 200 when the lower gyro 200 is combined or collided.

In some embodiments, as shown in fig. 4, the first coupling portion 3 includes a coupling recess 112 provided at the bottom of the upper mass 100, the upper tip 2 is retracted from the coupling recess 112 into the upper mass 100 when in the retracted position, and the second coupling portion 230 includes a coupling boss a cooperating with the coupling recess 112. Thus, when the upper gyroscope body 100 is combined with the lower gyroscope body 200, the two can form a stable gyroscope 1000, and the two are not easy to loosen during rotation.

Specifically, the first coupling portion 3 further includes a coupling magnetic member b provided in the upper gyro body 100, and the second coupling portion 230 further includes a coupling magnetic member b provided in the lower gyro body 200, and when the upper gyro body 100 is coupled to the lower gyro body 200, the two coupling magnetic members b attract each other, so that the two are attracted to a proper coupling position by attraction at the initial stage of coupling, and the stability of the two coupling during rotation is maintained under the action of magnetic force.

In some embodiments of the present invention, other structural improvements may be made on the upper gyroscope body 100 and the lower gyroscope body 200 to enrich the play of the gyroscope 1000.

For example, in some embodiments, as shown in fig. 3 and 4, the top of the upper gyroscope body 100 is provided with an accelerating portion 400, and the accelerating portion 400 is used for combining with the transmitting head 310 of the transmitter 300. The launcher 300 thus retrieves the upper mass 100 through the transmission head 310 and launches the upper mass 100 after accelerating it. The upper gyroscope body 100 is accelerated through the emitter 300, so that the upper gyroscope body is accelerated in a traditional whipping mode compared with a player, the operation is more convenient, and people are not easy to hurt. The acceleration portion 400 is provided on the top of the upper gyro 100, and less interference with the upper gyro 100 occurs when the upper gyro 100 is launched by the launcher 300.

In some embodiments, as shown in fig. 8, the top of the lower gyroscope 200 is also provided with an accelerating portion 400, and the accelerating portion 400 is used for combining with the transmitting head 310 of the transmitter 300. In this way, the launcher 300 can also retrieve the lower gyroscope 200 through the launching head 310 and launch the lower gyroscope 200 after accelerating.

Specifically, as shown in fig. 3 and 8, the top of the upper gyroscope 100 and the top of the lower gyroscope 200 are both provided with a combination protrusion a, and the accelerating portion 400 includes an accelerating block 401 disposed at the edge of the combination protrusion a, so that when the combination protrusion a extends into the transmitting head 310, the accelerating block 401 is clamped on the transmitting head 310, and the upper gyroscope 100 and the lower gyroscope 200 are ensured to rotate synchronously with the transmitting head 310.

More specifically, the top of the upper mass 100 is provided with a coupling magnetic member b, and the transmitting head 310 is also provided with a coupling magnetic member b, so that when the upper mass 100 is coupled to the transmitting head 310, more stable coupling can be ensured. Moreover, the magnetic force is set so that the transmitting head 310 can be directly combined with the upper mass 100 by sucking the upper mass 100 without manually pressing the upper mass 100 into the transmitting head 310. Likewise, the top of the lower mass 200 may also be provided with a coupling magnetic member b.

In some embodiments, as shown in fig. 3, the top of the upper gyroscope 100 is provided with a third combining portion 7, the upper gyroscope 100 is multiple, each upper gyroscope 100 can be independently combined to the top of the lower gyroscope 200 when the corresponding upper gyroscope tip 2 is in the retracted position, multiple upper gyroscopes 100 can be sequentially stacked in the up-down direction when the corresponding upper gyroscope tip 2 is in the retracted position, and the first combining portion 3 of the upper gyroscope 100 located above is combined with the third combining portion 7 of the upper gyroscope 100 located below. Thus, the top 1000 may have a single upper body 100 or multiple upper bodies 100.

Optionally, the third coupling portion 7 includes a coupling boss a engaged with the coupling groove 112. Thus, when the upper gyroscope body 100 on the upper layer is combined with the upper gyroscope body 100 on the lower layer, the two can form stable combination, and the two are not easy to loosen during rotation. Optionally, the third coupling portion 7 also includes a coupling magnetic member b.

In some embodiments, the top and bottom of the upper gyro 100 and the top of the lower gyro 200 are provided with the coupling magnetic members b.

The structure and play of a top 1000 in one embodiment is described below with reference to figures 1-14.

The gyroscope 1000 is played in a fighting plate and comprises an upper gyroscope body 100 and a lower gyroscope body 200, the upper gyroscope body 100 has the main function of upwards ejecting out after being collided by external force, and the lower gyroscope body 200 has the main function of changing attack states and defense states.

Upper gyroscope 100 structure: as shown in fig. 3-7, the upper gyroscope 100 mainly includes an upper gyroscope housing 12, an ejection member 4, an upper gyroscope housing 11, a locking disc 52, an upper gyroscope tip 2, a travel extending member 6, a return elastic member 53 and two combined magnetic members b.

When the spinning top 1000 rotates at a high speed, the lock disc 52 rotates a certain angle after being collided by other spinning tops, the upper top tip 2 is released after the lock disc 52 rotates a certain angle, the upper top shell 12 and the upper top lower shell 11 are upwards bounced under the action of the ejection piece 4, and the extension piece 6 plays a role in extending the ejection stroke. After ejection, the lock disc 52 is reset under the force of the reset spring 53.

The lower gyroscope 200 has the structure: as shown in fig. 8-10, the lower gyroscope 200 mainly includes a lower body 210, a coupling magnetic member b, a coupling trigger 261, a movable gyroscope pin, a fixed gyroscope pin, a centrifugal trigger 262, a centripetal elastic member 263, an elastic driving member 250, and a lower gyroscope tip 220.

When the upper gyro body 100 and the lower gyro body 200 are combined, the upper gyro body 100 presses the coupling trigger 261 to move downward, and the coupling trigger 261 presses the movable gyro needle to extend downward, so that the gyro 1000 becomes an attack state. When the upper gyroscope body 100 is ejected, the triggering member 261 is no longer pressed by the upper gyroscope body 100, and at this time, the elastic driving member 250 releases to move the movable gyroscope needle upward, so that the movable gyroscope needle is no longer in contact with the combat disk, and the gyroscope 1000 becomes a defense state.

When the lower gyroscope 200 rotates at a high speed in the combat tray, the centrifugal trigger 262 moves outwards under the action of centrifugal force, and the centrifugal trigger 262 presses the movable gyroscope needle to move downwards to contact with the ground, so that the gyroscope 1000 becomes an attack state. When the rotation speed of the lower gyroscope 200 is reduced, the centripetal elastic member 263 overcomes the centrifugal force to press, the centrifugal trigger 262 moves towards the middle, the movable gyroscope needle moves upwards under the acting force of the elastic driving member 250, and is no longer in contact with the ground, and the gyroscope 1000 becomes a defense state.

Condition for the lower mass 200 to become an attack state: 1. the upper mass 100 and the lower mass 200 are integrated; 2. after the upper mass 100 is ejected, the lower mass 200 is still rotating at a high speed.

Condition under which the lower mass 200 becomes defensive: the upper mass 100 is disengaged from the lower mass 200 and the rotation speed is reduced.

In this embodiment, when the transmitter 300 is used, the upper gyro 100 and the lower gyro 200 can be cycled between the "combined state, the separated state, and the combined state" for an unlimited number of times.

The toy comprises:

in step 1, as shown in fig. 11 and 12, the top 1000 is assembled to the launcher 300, the pulling rope is pulled to accelerate the top 1000, the launching button of the launcher 300 is pressed, and the top 1000 is launched into the fighting plate. In step 2, the top 1000 collides with other tops in the fighting plate to trigger the unlocking trigger 54 of the upper top body 100. In step 3, as shown in fig. 13, when the unlocking triggering member 54 of the upper gyro 100 is knocked, which corresponds to the locking assembly 5 being triggered, the upper gyro 100 is ejected upward, and the upper gyro 100 is separated from the lower gyro 200 and falls on the fighting plate to rotate. And step 4, moving the upper gyroscope 100 to the position above the upper gyroscope 100 by using the suction cup of the transmitting head 310 of the transmitter 300, and sucking the upper gyroscope 100 back to the transmitter 300. In step 5, the upper mass 100 is pressed downwards, so that the upper tip 2 returns to the retracted position. At step 6, the launcher 300 is pulled to pull the spinning top 1000. At step 7, as shown in fig. 14, the transmitter 300 is moved so that the upper gyro 100 is positioned above the lower gyro 200. In step 8, the upper gyro body 100 is dropped on the lower gyro body 200 by pressing the launch button of the lower launcher 300. In step 9, the lower gyroscope 200 is accelerated after being combined with the upper gyroscope 100, and the gyroscope 1000 can collide with other gyroscopes in the fighting plate, which is equivalent to returning to step 2, and the process is infinitely circulated.

In the description herein, references to the description of the terms "embodiment," "example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

While embodiments of the present invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.

Claims (12)

1. A spinning top, characterized in that the spinning top has a split state and a combined state, the spinning top comprises an upper spinning body and a lower spinning body, the upper spinning body and the lower spinning body are mutually independent toy bodies in the split state, the upper spinning body is combined on the top of the lower spinning body in the combined state, wherein,

the upper mass includes: the upper gyroscope comprises an upper body, an upper gyroscope tip, a first combining part, an ejection piece and a locking assembly, wherein the upper gyroscope tip is telescopically arranged at the bottom of the upper body, the upper gyroscope tip is provided with an extending position and a retracting position, the ejection piece is used for normally driving the upper gyroscope tip to eject towards the extending position, the locking assembly is matched with the upper gyroscope tip to lock the upper gyroscope tip at the retracting position, the locking assembly releases the upper gyroscope tip after being triggered to eject the upper gyroscope tip by the ejection piece, and the first combining part is arranged at the bottom of the upper gyroscope body;

the lower gyro includes: the lower top tip is arranged at the bottom of the lower body to support and rotate, the first combining part and the second combining part of the upper top body are combined when the upper top tip is in a retracted position, and the upper top body jumps away from the lower top body by popping up the upper top tip and supports and rotates when the locking assembly is released;

in addition, the upper gyroscope body can accelerate through the emitter, the upper gyroscope tip is enabled to move from the extending position to the retracting position, the ejector is driven to store energy, and the upper gyroscope body can be emitted to the lower gyroscope body through the emitter to be combined with the top of the lower gyroscope body.

2. The gyroscope according to claim 1, wherein the top of the upper gyroscope body is provided with a third engaging portion, the upper gyroscope body is provided in plurality, each of the upper gyroscope bodies is independently engageable with the top of the lower gyroscope body when the corresponding upper gyroscope tip is in the retracted position, the plurality of upper gyroscope bodies are sequentially stackable in the up-down direction when the corresponding upper gyroscope tip is in the retracted position, and the first engaging portion of the upper gyroscope body located above is engaged with the third engaging portion of the upper gyroscope body located below.

3. The gyroscope according to claim 1 or 2, characterized in that the upper gyroscope body and the lower gyroscope body are each provided, at the top, with an acceleration portion for coupling with the emission head of an emitter.

4. The gyroscope of claim 1, wherein the top and bottom of the upper gyroscope body and the top of the lower gyroscope body are provided with bonded magnetic members.

5. The gyroscope of claim 1, wherein the first coupling portion includes a coupling recess formed in a bottom portion of the upper gyroscope body, the upper gyroscope tip is retracted into the upper gyroscope body from the coupling recess when in the retracted position, and the second coupling portion includes a coupling boss engaged with the coupling recess.

6. The gyroscope of claim 1, wherein the lower gyroscope body further comprises: top needle, elastic driving spare and trigger subassembly, the top needle is at least one, but at least one in the top needle is flexible activity top needle from top to bottom and has primary importance and second place, at primary importance and second place the activity top needle is relative down the length that the body stretches out is different, elastic driving spare with the activity top needle links to each other with normal drive the activity top needle moves towards primary importance, trigger subassembly drive when triggering the activity top needle moves towards the second place.

7. The top of claim 6, wherein the trigger assembly comprises: the upper gyroscope body is movably arranged on the upper body, the bottom of the combination trigger piece is matched with the movable gyroscope needle, and when the upper gyroscope body is combined to the lower gyroscope body, the upper gyroscope body is pressed on the combination trigger piece in a propping mode, so that the combination trigger piece drives the movable gyroscope needle to move.

8. The top of claim 6, wherein the trigger assembly comprises: the centrifugal trigger piece is movable along the radial direction of the lower gyroscope body and matched with the movable gyroscope needle, and when the rotating speed of the lower gyroscope body exceeds a set rotating speed, the centrifugal trigger piece pushes the movable gyroscope needle to move.

9. The top of claim 1, wherein the upper top body further comprises: the range extending piece is arranged on the upper body in a vertically sliding mode, the upper gyro tip is arranged on the range extending piece in a vertically sliding mode, and the ejection piece and the locking assembly act on the upper gyro tip.

10. The top of claim 9, wherein the upper body comprises:

the upper gyroscope lower shell is provided with a telescopic hole in the center, the stroke extending piece is a stroke extending pipe and is matched in the telescopic hole in a sliding manner, and the upper gyroscope tip is matched in the stroke extending pipe in a sliding manner;

and the upper gyroscope shell is covered on the lower gyroscope shell and covers the range extending piece.

11. The top of claim 10, wherein the locking assembly comprises:

the locking disc is rotatably arranged on the upper gyroscope body and arranged around the stroke extending pipe, the locking disc is provided with a locking position, and a locking block clamped at the locking position on the upper gyroscope tip is arranged on the inner wall of the locking disc;

the reset elastic piece is connected to the lock disc so as to drive the lock disc to rotate towards a locking position;

the unlocking trigger piece is connected with the lock disc and triggers the lock disc to deviate from a locking position so as to release the upper gyroscope point.

12. The gyroscope according to claim 11, wherein a first mating groove is formed in an inner wall of the telescopic hole, a second mating groove corresponding to the first mating groove is formed in a tube wall of the range extending tube, a mating block which is fitted in the second mating groove is formed in an outer wall of the upper gyroscope top, and in the locking position, the locking block is located above the first mating groove and is clamped below the mating block.

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