CN214105806U

CN214105806U - Gyro emitter

Info

Publication number: CN214105806U
Application number: CN202022634327.8U
Authority: CN
Inventors: 梁文建; 李德铭
Original assignee: Alpha Group Co Ltd; Guangzhou Alpha Culture Co Ltd
Current assignee: Alpha Group Co Ltd; Guangzhou Alpha Culture Co Ltd
Priority date: 2020-11-13
Filing date: 2020-11-13
Publication date: 2021-09-03
Anticipated expiration: 2030-11-13

Abstract

The utility model discloses a gyro launcher, which comprises a launching body, a linkage piece and a gyro toy, wherein the linkage piece can move between an assembly position and a launching position on the launching body; the top body is provided with an accelerating component capable of driving the top toy to rotate; the top toy is detachably mounted to the linkage member when the linkage member is in the assembled position; when the linkage piece is in the launching position, the top toy arranged on the linkage piece is connected with the accelerating assembly; when the accelerating component accelerates the top toy, the trigger of the launching body is triggered, and the top toy is launched from the linkage piece by the launching body. The utility model discloses in remove and be connected with the subassembly with higher speed to the transmission position through the linkage, drive the top toy with higher speed, after pulling the trigger, launch away linkage and top toy together to the transmission of top toy has been realized. Realize linkage transmission top toy through the linkage, increased maneuverability, interest and the object for appreciation nature of toy.

Description

Gyro emitter

Technical Field

The utility model relates to a technical field of top toy transmitter especially relates to a top transmitter.

Background

The existing mainstream top toy launcher mainly accelerates the top toy through manually pulling a rack or a rope, and releases the top toy and launches the top toy after the top toy is accelerated to a certain speed. The existing top toy launcher is in a handle shape, or a gun shape. The modeling of the emitter is single, only the acceleration of the gyro toy is realized, the interestingness is lacked, and the attraction to children is reduced after the gyro toy is played for a long time.

Therefore, there is a need for a top launcher with novel design, increased interest and playability.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome the not enough of prior art, provide a top transmitter that novel structure, interest and playability are higher.

The technical scheme of the utility model provides a top launcher, which comprises a launching body, a linkage piece and a top toy, wherein the linkage piece can move between an assembly position on the launching body and the launching position;

the launching body is provided with an accelerating component capable of driving the spinning top toy to rotate; the top toy is detachably mounted to the linkage member when the linkage member is in the assembled position; when the linkage piece is in the launching position, the top toy installed on the linkage piece is connected with the accelerating component; when the acceleration assembly accelerates the top toy, the trigger of the launching body is triggered, and the top toy is launched from the linkage piece by the launching body.

Furthermore, the top toy also comprises an elastic piece, when the linkage piece is in a launching position and the trigger is pulled down, the elastic piece ejects the linkage piece to the assembling position, and the top toy is triggered to be launched by moving the linkage piece to the assembling position.

Furthermore, a locking piece used for locking the linkage piece in the launching state is arranged in the launching body, the locking piece is linked with the trigger, the elastic piece is arranged on the linkage piece, and the elastic piece stores energy when in a launching position;

when the trigger is pulled down, the locking piece unlocks the linkage piece, the elastic piece drives the linkage piece to move from the launching position to the assembling position, and the spinning top toy is triggered to be launched out through the movement of the linkage piece.

Further, the linkage includes a movable member configured to a first configuration when the movable member is in a first position and a second configuration when the movable member is in a second position;

when the trigger is pulled down, the linkage piece is triggered to deform from the first form to the second form.

Further, the movable member includes a holding movable member which is in an open state in the fitting position and in a holding state in the launching position to hold the top toy therein, the top toy being connected to the link member through the holding movable member.

Further, the clamping movable piece comprises an upper clamping part and a lower clamping part;

when the clamping movable piece is in the opening state, the top toy is connected with the upper clamping part;

when the clamping movable piece is in the clamping state, the lower clamping part compresses the gyro toy, and the gyro toy is connected with the acceleration assembly through the upper clamping part.

Furthermore, the upper clamping part is provided with engaging teeth, and the emission body is provided with a rear compression buckle;

before the linkage piece moves to the launching position, the accelerating assembly is lifted upwards, and the rear pressing and releasing piece extends forwards;

when the linkage piece moves to the launching position, the upper clamping part presses the rear pressing and releasing fastener, the rear pressing and releasing fastener drives the accelerating assembly to be downwards meshed with the meshing teeth, and the accelerating assembly drives the gyro toy to accelerate through the meshing teeth;

the trigger is linked with the accelerating component, and when the trigger is pulled, the accelerating component is lifted upwards again and separated from the occlusion teeth.

Furthermore, a brake block is arranged on the linkage piece, when the linkage piece moves to the assembling position, the linkage piece deforms to the second shape, and the linkage piece drives the brake block to bump and stop the meshing teeth.

Further, the interlock tooth includes interlock slot, tooth body and braking wheel, the interlock slot is located the top surface of last clamping part, insert with higher speed the bolt of subassembly in the interlock slot, tooth body and the linkage of one-way face gear, one-way face gear drives top toy rotates with higher speed, the braking stop with during the braking wheel is contradicted, interlock tooth stall makes one-way face gear stall, top toy with one-way face gear separation.

Furthermore, a transmission part is arranged in the linkage part, the input end of the transmission part is connected with the acceleration component, the output end of the transmission part is connected with the top toy installed on the linkage part, and the acceleration component drives the top toy to store power energy when being driven.

After adopting above-mentioned technical scheme, have following beneficial effect:

the utility model discloses in remove and be connected with the subassembly with higher speed to the transmission position through the linkage, drive the top toy with higher speed, after pulling the trigger, launch away linkage and top toy together to the transmission of top toy has been realized. Realize linkage transmission top toy through the linkage, increased maneuverability, interest and the object for appreciation nature of toy.

Drawings

The disclosure of the present invention will become more readily understood by reference to the drawings. It should be understood that: these drawings are for illustrative purposes only and are not intended to limit the scope of the present disclosure. In the figure:

FIG. 1 is a schematic view of a linkage of a top launcher according to an embodiment of the present invention in a second configuration;

FIG. 2 is a schematic view of a linkage of a top launcher according to an embodiment of the present invention in a first configuration;

FIG. 3 is an illustration of a linkage member of a top launcher according to an embodiment of the present invention in a first configuration;

FIG. 4 is a schematic view of a linkage member in a first configuration in accordance with an embodiment of the present invention;

FIG. 5 is a schematic view of the internal structure of the linkage member in the first configuration according to an embodiment of the present invention;

fig. 6 is a partially enlarged view of the first linking gear according to an embodiment of the present invention;

fig. 7 is a schematic view of a first linkage gear inserted into the torso portion in an embodiment of the invention;

FIG. 8 is a schematic view of the internal structure of the linkage member in a second configuration in accordance with an embodiment of the present invention;

fig. 9 is a cross-sectional view of a head portion of a linkage member in an embodiment of the invention;

FIG. 10 is an enlarged view of a portion of a linkage member according to an embodiment of the present invention;

FIG. 11 is a partial enlarged view of the internal structure of the head according to an embodiment of the present invention;

fig. 12 is a partially enlarged view of the internal structure of the accelerating assembly in an embodiment of the present invention;

fig. 13 is a partial enlarged view of the internal structure of the launching body when the accelerating assembly is lifted upward in an embodiment of the present invention;

fig. 14 is a partial enlarged view of the internal structure of the launching body when the accelerating assembly is connected to the head according to an embodiment of the present invention.

Reference symbol comparison table:

the emitter body 1: the device comprises an acceleration component 11, a trigger 12, a launching slot 13, a rear-pressure release fastener 14, a second lock catch 15, a limit block 16, a sliding groove 17, a handle 18, a bolt 111, a pull ring 112, an energy accumulator 113, a transmission gear set 114, an acceleration shell 115, a limit slot 1151 and a toggle block 1152;

the linkage 2: arm 20, head 21, trunk 22, tail 23, linkage gear set 24, occlusion tooth 25, one-way face gear 26, first lock catch 27, first magnetic element 28, leg 29, foot 30, upper jaw 211, lower jaw 212, transmission gear 213, brake stop block 221, first linkage gear 241, second linkage gear 242, third linkage gear 243, occlusion slot 251, tooth body 252, brake stop wheel 253;

the top toy 3: a second magnetic element 31.

Detailed Description

The following describes the present invention with reference to the accompanying drawings.

It is easily understood that, according to the technical solution of the present invention, a plurality of structural modes and implementation modes that can be mutually replaced by those of ordinary skill in the art can be achieved without changing the spirit of the present invention. Therefore, the following detailed description and the accompanying drawings are only exemplary illustrations of the technical solutions of the present invention, and should not be construed as limiting or restricting the technical solutions of the present invention in its entirety or as a limitation of the present invention.

The terms of orientation of up, down, left, right, front, back, top, bottom, and the like referred to or may be referred to in this specification are defined relative to the configuration shown in the drawings, and are relative terms, and thus may be changed correspondingly according to the position and the use state of the device. Therefore, these and other directional terms should not be construed as limiting terms.

In an embodiment of the present invention, as shown in fig. 1, the top launcher includes a launching body 1, a linkage member 2 and a top toy 3, wherein the linkage member 2 can move between an assembling position and a launching position of the launching body 1;

in this embodiment, the front end of the launching body 1 is an assembly position, and the rear end is a launching position.

The launching body 1 is provided with an accelerating component 11 which can drive the spinning top toy 3 to rotate; the top toy 3 is detachably mounted to the link 2 when the link 2 is in the fitting position; when the linkage member 2 is in the launching position, the top toy 3 mounted on the linkage member 2 is connected with the accelerating assembly 11; when the acceleration assembly 11 accelerates the top toy 3 and then pulls the trigger 12 of the launching body 1, the launching body 1 launches the top toy 3 from the linkage 2.

In particular, as shown in fig. 1, the linkage 2 is in the assembled position. At this time, the link 2 is located at the foremost end (left side of fig. 1) of the launching body 1, and the top toy 3 is put into the link 2.

As shown in fig. 2, the linkage 2 is in the firing position. The linkage piece 2 slides backwards (right side in figure 1) and is connected with an accelerating component 11, the accelerating component 11 is positioned above the linkage piece 2, and the top toy 3 is accelerated through the transmission of the linkage piece 2.

When the top toy 3 is accelerated to a certain speed, the trigger 12 is pulled, the trigger 12 releases the accelerating assembly 11, so that the accelerating assembly 11 is separated from the linkage 2, meanwhile, the trigger 12 also releases the linkage 2, and the linkage 2 is ejected forwards under the action of the tension spring. The top toy 3 is separated from the linkage member 2 at this time, falls on the ground or the game table, and keeps rotating for a certain time.

Besides the linkage member 2 driven by the tension spring to eject forwards, an ejection member can be arranged on the launching body 1, and when the trigger 12 is pulled, the ejection member ejects forwards to impact the linkage member 2, so that the linkage member 2 moves forwards.

The linkage 2 in this embodiment can drive the gyro toy 3 to the acceleration component 11 of the launching body 1, and the acceleration of the gyro toy 3 is realized. By pulling the trigger 12, the launching of the top toy 3 is realized by the linkage with the trigger 12. Realize linkage transmission top toy 3 through linkage 2, increased maneuverability, object for appreciation nature and the interest of toy.

Furthermore, the toy gyroscope further comprises an elastic piece, when the linkage piece 2 is in the launching position and the trigger 12 is pulled down, the elastic piece ejects the linkage piece 2 to move to the assembling position, and the toy gyroscope 3 is triggered to be launched when the linkage piece 2 moves to the assembling position.

In this embodiment, the elastic member is a tension spring (not shown), one end of the tension spring is connected to the linkage member 2, and the other end is connected to the launching body 1. When the linkage 2 moves to the launching position, the tension spring is stretched to store energy; when the trigger 12 is pulled, the linkage member 2 is released, the tension spring releases energy, the linkage member 2 moves towards the assembling position quickly, and the spinning top toy 3 is launched out.

Further, the linkage 2 comprises a movable part, the linkage 2 being configured in a first configuration when the movable part is in a first position, the linkage 2 being configured in a second configuration when the movable part is in a second position;

when the trigger 12 is pulled, the trigger link 2 deforms from the first configuration to the second configuration.

In this embodiment, the firing body 1 is gun-shaped, the firing body 1 includes a chute 17, a firing slot 13, and a handle 18, and the trigger 12 is mounted at the handle 18. The link 2 can slide back and forth along the slide groove 17 and enter the launching slot 13 when sliding backward.

In this embodiment, as shown in fig. 1, the link 2 has an animal shape, the link 2 includes a head portion 21, a trunk portion 22 and a tail portion 23, the head portion 21, the trunk portion 22 and the tail portion 23 are movable members, the top toy 3 is connected to the head portion 21, and when the link 2 moves backward to be connected to the acceleration assembly of the launching body 1, the head portion 21, the trunk portion 22 and the tail portion 23 are rotatably folded and received in the launching slot 13 of the launching body 1.

Specifically, as shown in fig. 1, in the second mode, the head 21, the trunk 22, and the tail 23 are spread out in a dinosaur configuration.

As shown in fig. 3 to 4, in the first embodiment, the body portion 22 rotates clockwise with respect to the head portion 21 until the body portion 22 abuts against the head portion 21 and cannot rotate any further, and at this time, the head portion 21 and the body portion 22 are substantially perpendicular to each other. The tail portion 23 rotates clockwise with respect to the trunk portion 22 and is retracted to the bottom, and the tail portion 23 is substantially perpendicular to the trunk portion 22.

As shown in fig. 1, the link 2 further includes a leg portion 29 and a foot portion 30, the leg portion 29 is rotatably connected to the trunk portion 22 via a torsion spring (not shown) and a rotation shaft (not shown), and the leg portion 29 is rotatably connected to the foot portion 30 via a torsion spring and a rotation shaft.

As shown in fig. 3, in the first mode, the leg portions 29 and the leg portions 30 are also rotated clockwise and accommodated in a state substantially perpendicular to each other with respect to the trunk portion 22. At this time, the link 2 is substantially a cube and can be received in the launching groove 13 (see fig. 1) of the launching body 1.

Alternatively, the link 2 is not limited to the dinosaur model, but may be a tiger model, a dog model, an animal model such as a bird model, a transformable airplane model, an automobile model, or the like.

Further, the movable member includes a holding movable member which is in an open state in the fitting position and in a holding state in the launching position to hold the top toy 3 therein, the top toy 3 being connected to the link 2 by the holding movable member.

In this embodiment, the head 21 is a holding movable member, and can hold the top toy 3 therein.

when the clamping movable piece is in an open state, the top toy 3 is connected with the upper clamping part;

when the clamping movable piece is in a clamping state, the lower clamping part compresses the top toy 3, and the top toy 3 is connected with the accelerating assembly 11 through the upper clamping part.

In this embodiment, as shown in fig. 4, the head 21 includes an upper jaw 211 and a lower jaw 212, the upper jaw 211 being an upper holding portion, the lower jaw 212 being a lower holding portion, and the top toy 3 being attached to the upper jaw 211 and located between the upper jaw 211 and the lower jaw 212;

the linkage 2 moves forward backward, and the upper jaw 211 and the lower jaw 212 open;

when the link 2 moves backward to be connected to the accelerating assembly 11 of the launching body 1, the lower jaw 212 rotates upward to hold the lower portion of the top toy 3.

Specifically, as shown in fig. 8, in the second mode, the upper jaw 211 and the lower jaw 212 are opened, the upper jaw 211 and the lower jaw 212 are rotatably connected, and a torsion spring (not shown) is mounted at the rotating position.

In the first form, the link 2 is folded in a rotating manner, the arm 20 of the link 2 is connected with the trunk 22, when the trunk 22 rotates clockwise, the arm 20 is driven to rotate clockwise, when the arm 20 rotates to be abutted against the lower jaw 212, the lower jaw 212 is driven to rotate upwards together, so that the lower jaw 212 rotates towards the upper jaw 211, and the dinosaur-shaped mouth is closed.

As shown in fig. 2, the lower jaw 212 restrains the top toy 3 therein after the mouth of the dragon is closed, but the lower jaw 212 does not affect the rotation of the top toy 3 at the time of acceleration.

Further, as shown in fig. 5, a linkage gear set 24 is provided inside the head 21, the trunk 22 and the tail 23, and when the head 21 is pressed downward, the linkage gear set 24 is driven to rotate, and the linkage gear set 24 drives the trunk 22 and the tail 23 to rotate and fold.

Specifically, as shown in fig. 6, the linkage gear set 24 includes a first linkage gear 241, the first linkage gear 241 is fixedly connected to the upper jaw 211, and when the head 21 is pressed downward, the upper jaw 211 drives the first linkage gear 241 to rotate together.

As shown in fig. 7, when mounted, the first link gear 241 is inserted into the body portion 22.

As shown in fig. 5, the linkage gear set 24 further includes a second linkage gear 242, the second linkage gear 242 being provided in the trunk portion 22, the second linkage gear 242 being meshed with the first linkage gear 241. When the head 21 drives the first linkage gear 241, the second linkage gear 242 is driven to rotate together.

As shown in fig. 5 and 8, the linkage gear set 24 further includes a third linkage gear 243, and the third linkage gear 243 is disposed in the tail portion 23 and is fixedly connected to the tail portion 23. The second linkage gear 242 drives the third linkage gear 243 to rotate, so that the third linkage gear 243 drives the tail portion 23 to rotate to the first configuration, and the tail portion is retracted into the bottom of the trunk portion 22.

In this embodiment, the head portion 21, the trunk portion 22 and the tail portion 23 are rotatably connected by a torsion spring. In the second state, when the head 21 is pressed downward and rearward, the folding of the tail 23 is achieved by the interlocking gear set 24. The head part 21 rotates counterclockwise downward toward the trunk part 22 until interfering with the trunk part 22, and then the head part 21 and the trunk part 22 rotate clockwise with respect to the leg parts 29 and the foot parts 30 together, and push the leg parts 29 and the foot parts 30 to rotate clockwise, so that the dinosaur-shaped linkage 2 is rotatably folded into the first configuration.

When the linkage 2 is released by the trigger 12, the linkage 2 returns to the second configuration under the action of a torsion spring (not shown) at each rotational connection. At this time, the interlocking gear set 24 is driven to rotate in the reverse direction.

Further, as shown in fig. 10-11 and fig. 13-14, the head 21 is provided with engaging teeth 25, and the launching body 1 is provided with a rear release fastener 14;

before the linkage piece 2 moves backwards, the accelerating component 11 is lifted upwards, and the rear buckling and releasing fastener 14 extends forwards;

when the linkage piece 2 moves backwards to be connected with the accelerating component 11 of the launching body 1, the head 21 presses the rear-pressing releasing fastener 14, the rear-pressing releasing fastener 14 drives the accelerating component 11 to be downwards meshed with the meshing teeth 25, and the accelerating component 11 drives the top toy 3 to accelerate through the meshing teeth 25;

the trigger 12 is coupled to the acceleration assembly 11, and when the trigger 12 is pulled, the acceleration assembly 11 is again lifted upward and separated from the engagement teeth 25.

Specifically, as shown in fig. 13, the accelerating assembly 11 is lifted upwards by the torsion spring (not shown), and the latch 111 of the accelerating assembly 11 is separated from the engaging tooth 25. The accelerating component 11 extends downwards to form a poking block 1152, when the accelerating component 11 is lifted upwards, the poking block 1152 pokes the rear buckling piece 14 forwards, so that at least part of the rear buckling piece 14 extends out of the shell of the launching body 1.

The acceleration assembly 11 further includes an acceleration housing 115, and a limiting groove 1151 is formed on the acceleration housing 115. The trigger 12 is linked with a stopper 16. When the accelerating assembly 11 is lifted upward, the stopper 16 is separated from the stopper groove 1151.

As shown in fig. 14, when the linkage 2 moves backward, the head 21 presses the rear release 14, the rear release 14 retracts into the housing of the launching body 1, and the dial block 1152 is dialed to the right, and the dial 1152 rotates the accelerating assembly 11 downward, so that the latch 111 of the accelerating assembly 11 is inserted into the engaging tooth 25.

After the accelerating assembly 11 is rotated downwards, the limiting block 16 is inserted into the limiting groove 1151, and is used for keeping the accelerating assembly 11 at a position of being connected with the meshing teeth 25 for transmission. The acceleration assembly 11 is capable of accelerating the top toy 3 through the engagement teeth 25.

When the top toy 3 is accelerated to a certain speed, the trigger 12 is pulled, the trigger 12 moves backwards, the limit block 16 is pushed to move backwards, the limit block 16 is separated from the limit groove 1151, and the accelerating component 11 is lifted upwards under the action of the torsion spring of the accelerating component and is separated from the meshing teeth 25.

In this embodiment, as shown in fig. 12-13, the acceleration assembly 11 further includes a pull ring 112, an accumulator 113, and a drive gear set 114.

The accumulator 113 and the driving gear set 114 are installed in the acceleration housing 115, and the pull ring 112 is located outside the acceleration housing 115. The pull ring 112 is connected to one end of a pull cord (not shown) and the other end of the pull cord is connected to an accumulator 113.

When the vehicle is accelerated, the pull ring 112 is pulled back to drive the energy accumulator 113 to accumulate energy, the energy accumulator 113 drives the transmission gear set 114 to rotate, the transmission gear set 114 drives the bolt 111 to rotate, and the bolt 111 drives the meshing teeth 25 to rotate.

Further, as shown in fig. 10, a brake block 221 is arranged on the trunk portion 22, when the linkage member 2 is ejected forwards, the head portion 21, the trunk portion 22 and the tail portion 23 rotate and unfold, and the trunk portion 22 drives the brake block 221 to bump against the meshing teeth 25.

Specifically, the brake pad 221 is disposed at the neck portion of the body portion 22, extends from the connection portion of the body portion 22 and the head portion 21, and extends into the housing of the head portion 21.

When the acceleration assembly 11 accelerates the top toy 3, the engaging teeth 25 are driven to rotate, and after the trigger 12 is pulled, the linkage part 2 is released, so that the head part 21, the body part 22 and the tail part 23 rotate and unfold to the second shape. In the unfolding process, the brake block 221 stops the meshing teeth 25 to stop the rotation of the meshing teeth 25, at the moment, the spinning top toy 3 continues to rotate under the action of inertia and is separated from the linkage with the meshing teeth 25, and the spinning top toy 3 falls onto the ground or a game platform to continue to rotate and play.

Further, as shown in fig. 10 to 11, the engaging tooth 25 includes an engaging slot 251, a tooth body 252 and a brake wheel 253, the engaging slot 251 is located on the top surface of the head 21, the latch 111 of the acceleration assembly 11 is inserted into the engaging slot 251, the tooth body 252 is linked with the one-way face gear 26, and the one-way face gear 26 drives the top toy 3 to rotate at an acceleration. When the brake block 221 collides with the brake wheel 253, the rotation of the engaging tooth 25 is stopped, so that the rotation of the unidirectional face gear 26 is stopped, and the spinning top toy 3 is separated from the unidirectional face gear 26.

Wherein the engagement slot 251 is located on the top surface of the head portion 21, so as to facilitate the insertion of the latch 111 of the acceleration assembly 11 into the engagement slot 251; the tooth body 252 is positioned below the occlusion slot 251 and is in transmission connection with the one-way face gear 26 through the transmission gear 213; the brake wheel 253 is located at the bottom of the gear body 252, and the brake wheel 253 comprises four gear teeth, when one of the gear teeth interferes with the brake block 221, the engaging gear 25 stops rotating, so that the transmission gear 213 and the one-way face gear 26 also stop rotating.

As shown in fig. 4, the one-way face gear 26 is exposed from the bottom of the upper jaw 211 to be engaged with the top toy 3.

As shown in fig. 8, the unidirectional face gear 26 is provided with a plurality of unidirectional face teeth, and the top toy 3 is provided with corresponding teeth which are engaged with the unidirectional face gear 26. The unidirectional face gear 26 can drive the top toy 3 to rotate only in one direction. When the unidirectional face gear 26 stops rotating, the top toy 3 continues to rotate under the action of inertia, and the inclined face of the unidirectional face gear 26 pushes the top toy 3 downwards, so that the top toy 3 is separated from the unidirectional face gear 26 and falls onto the ground or a game table.

Further, be equipped with the driving medium in the linkage 2, the input of driving medium with the subassembly 11 is connected with higher speed, the output of driving medium with install the top toy 3 on the linkage 2 and be connected, drive top toy 3 power energy storage when the subassembly 11 is driven with higher speed.

In this embodiment, the unidirectional face gear 26 and the meshing teeth 25 are transmission members, and the transmission between the acceleration assembly 11 and the top toy 3 is realized through the unidirectional face gear 26 and the meshing teeth 25.

Alternatively, the acceleration transmission between the acceleration assembly 11 and the top toy 3 may be realized by other transmission members.

Furthermore, a locking piece used for locking the linkage piece 2 in a launching state is arranged in the launching body 1, the locking piece is linked with the trigger 12, the elastic piece is arranged on the linkage piece 2, and the elastic piece stores energy when in a launching position;

when the trigger is pulled down, the locking piece unlocks the linkage piece 2, the elastic piece drives the linkage piece 2 to move from the launching position to the assembling position, and the top toy 3 is triggered to be launched through the movement of the linkage piece 2.

In this embodiment, as shown in fig. 3-5, the locking member is a second lock catch 15, the linkage member 2 is provided with a first lock catch 27, and the second lock catch 15 is arranged on the launching body 1;

when the linkage piece 2 moves backwards, the linkage piece is locked with the first lock catch 27 and the second lock catch 15 and is kept at the rear end of the launching body 1;

the trigger 12 is coupled to the second lock 15, and the second lock 15 is unlocked from the first lock 27 after the trigger 12 is pulled.

Specifically, the first lock catch 27 is disposed at the bottom of the foot 30, the foot 30 is rotatably connected to the first lock catch 27, and the first lock catch 27 can slide back and forth along the slide slot 17 of the launching body 1.

When the link 2 is moved rearwardly into engagement with the accelerator assembly 11, the first striker 27 slides into a locked position with the second striker 15, retaining the link 2 in that position.

The second lock catch 15 is disposed in the housing of the launching body 1, the second lock catch 15 is linked with the trigger 12, and when the trigger 12 is pulled, the second lock catch 15 is driven to move backwards, so that the second lock catch 15 is separated from the first lock catch 27. The first lock catch 27 is connected with a tension spring, and the linkage member 2 is ejected forwards under the action of the tension spring and slides to the foremost end of the launching body 1 quickly.

Further, as shown in fig. 9, the first magnetic element 28 is provided in the link 2, the second magnetic element 31 is provided in the top toy 3, and the top toy 3 is attracted to the link 2 by the attraction of the first magnetic element 28 and the second magnetic element 31.

Specifically, the first magnetic member 28 is disposed inside the one-way face gear 26, and when the top toy 3 is placed in the head 21, the first magnetic member 28 and the second magnetic member 31 attract each other, so that the top toy 3 can be quickly engaged with the one-way face gear 26.

When the unidirectional face gear 26 stops rotating, the top toy 3 continues to rotate, the inclined face of the unidirectional face gear pushes the top toy 3 downwards, so that the top toy 3 is separated from the unidirectional face gear 26, the magnetic force between the first magnetic element 28 and the second magnetic element 31 is not enough to adsorb the top toy 3, and the top toy 3 falls on the ground or a game table.

One of the play methods of the gyro transmitter in the present embodiment is as follows:

as shown in fig. 1, when the link 2 is in the second configuration, the toy top 3 is placed in the mouth of the dinosaur figure, and the toy top 3 is engaged with the one-way face gear 26.

The head 21 is then pushed downwardly and rearwardly, causing the link 2 to be rotationally folded into the first configuration of figure 2 and locked in the firing slot 13. At this point, the accelerator assembly 11 is flipped downward and engages the engagement teeth 25 in the head 21.

The pull ring 112 of the acceleration assembly 11 is rapidly pulled back and forth to accelerate the top toy 3.

When accelerating to the desired speed, trigger 12 is pulled and trigger 12 unlocks linkage 2, releasing acceleration assembly 11 to lift upward and disengage it from linkage 2. The linkage piece 2 is rapidly ejected forwards under the action of the tension spring, and in the ejecting process, the linkage piece 2 is unfolded from the first form to the second form. When the top toy 3 is unfolded to the second shape, the top toy 3 is separated from the linkage 2, and the top toy 3 falls on the ground or the game table and keeps rotating for a certain time.

The utility model provides a linkage 2 can expand when launching top toy 3 and warp into animal's molding, has increased the interest and the object for appreciation nature of toy.

What has been described above is merely the principles and preferred embodiments of the present invention. It should be noted that, for those skilled in the art, on the basis of the principle of the present invention, several other modifications can be made, and the protection scope of the present invention should be considered.

Claims

1. A top launcher comprising a launching body, a linkage movable between an assembly position and a launch position on the launching body, and a top toy;

2. The top launcher according to claim 1, further comprising a resilient member that, when the trigger is pulled down in a launch position, springs out the linkage to the assembly position, and the top toy is triggered to launch by the linkage moving to the assembly position.

3. The top launcher according to claim 2, wherein a locking member for locking the linkage member in a launching state is provided in the launching body, the locking member is linked with the trigger, the elastic member is provided on the linkage member, and the elastic member stores energy in a launching position;

4. The top launcher according to claim 1, wherein the linkage comprises a movable member, the linkage configured in a first configuration when the movable member is in a first position, the linkage configured in a second configuration when the movable member is in a second position;

5. The top launcher according to claim 4, wherein the movable member comprises a gripping movable member, the gripping movable member being in an open state in the assembled position and in a gripping state in the launch position to grip the top toy therein, the top toy being coupled to the linkage member by the gripping movable member.

6. The top launcher according to claim 5, wherein the clamping movable member comprises an upper clamping portion and a lower clamping portion;

7. The top launcher according to claim 6, wherein the upper clamping portion has engaging teeth, and the launching body has a rear compression release fastener;

8. The top launcher according to claim 7, wherein a stop block is provided on the linkage member, and when the linkage member moves to the assembly position, the linkage member deforms to the second configuration, and the linkage member drives the stop block to strike the engagement teeth.

9. The top launcher according to claim 8, wherein the engaging teeth comprise an engaging slot, a tooth body and a braking wheel, the engaging slot is located on the top surface of the upper clamping portion, the plug pin of the acceleration assembly is inserted into the engaging slot, the tooth body is linked with a unidirectional face gear, the unidirectional face gear drives the top toy to rotate in an acceleration manner, when the braking block is abutted against the braking wheel, the engaging tooth stops rotating, the unidirectional face gear stops rotating, and the top toy is separated from the unidirectional face gear.

10. The top launcher according to claim 1, wherein a transmission member is disposed in the linkage member, an input end of the transmission member is connected to the acceleration member, an output end of the transmission member is connected to the top toy mounted on the linkage member, and the acceleration member drives the top toy to store energy by power when being driven.