CN112386922A - Linkage multi-playing-method launching device - Google Patents

Abstract

The invention discloses a linkage multi-play-method launching device, which comprises a launching body, a linkage piece and a launched object, wherein the launching body is provided with a launching body; the linkage piece is arranged outside the launching body; the shot object is detachably arranged on the linkage piece, and the linkage piece can drive the shot object to move from an assembling position to a shooting position on the shooting body; when the launched object is in the launching position and the trigger of the launching body is pulled down, the launched object is launched out. The launching body is connected with the linkage piece, the linkage piece can drive the launched object to move from the assembling position to the launching position, and the launched object is launched out through the linkage piece. The invention realizes linkage emission of the emitted object through the linkage piece instead of monotonous emission of the emitted object from the emitting device, increases linkage play methods of the linkage piece, combines multiple play methods, and effectively improves the operability, playability and interestingness of the emitting device.

Description

Linkage multi-playing-method launching device

Technical Field

The invention relates to the technical field of toys, in particular to a linkage multi-playing-method launching device.

Background

The existing launching toy has single function and can only accelerate and launch the launched object. The emitting device has low playability, and children easily lose interest and cannot play for a long time.

Therefore, there is a need for a linked multi-play launching device that can achieve linked launching and is more playable and interesting.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provide a linkage multi-playing method launching device which can realize linkage launching and has stronger playability and interestingness.

The technical scheme of the invention provides a linkage multi-play-method launching device which comprises a launching body, a linkage piece and a launched object;

the linkage piece is arranged outside the launching body;

the shot object is detachably arranged on the linkage piece, and the linkage piece can drive the shot object to move from an assembling position to a shooting position on the shooting body;

when the launched object is in the launching position and the trigger of the launching body is pulled down, the launched object is launched out.

Further, the link is slidable or swingable between the fitting position and the firing position on the firing body.

Further, the launched object is directly mounted into the linkage; or, the emission body comprises a bullet hooking component, and the shot object is brought into the linkage piece by the bullet hooking component.

Further, the launching device also comprises a storage object, a plurality of launched objects are installed in the storage object, and the storage object is detachably installed in the launching body;

the bullet hooking component is used for driving one shot object in the storage object to enter the linkage part.

Further, the emission body comprises an operation assembly, and the operation assembly is used for driving the linkage piece to slide or swing.

Furthermore, the emission body also comprises an elastic hooking component, the elastic hooking component is used for bringing the emitted object into the linkage piece, and the operation component is linked with the elastic hooking component.

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, an 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 launched object is triggered to be launched through the movement of the linkage piece.

Furthermore, a launching part used for launching the launched object away from the linkage part is arranged in the launching body, and the launching part is linked with the trigger;

when the trigger is pulled down, the launching piece drives the launched object to be launched.

Furthermore, a locking piece is arranged on the linkage piece, and when the launched object leaves the linkage piece, the launched object triggers the locking piece to unlock so that the linkage piece moves.

Furthermore, a launching part used for launching the launched object away from the linkage part is arranged in the launching body, and the launching part is linked with the trigger;

when the trigger is pulled down, the linkage piece is triggered to move simultaneously, and the object to be shot is shot.

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 launching body further comprises a sliding platform, the linkage piece is connected to the sliding platform in a sliding mode, and when the trigger is pulled down, the linkage piece moves from one end of the sliding platform to the other end of the sliding platform or moves from the sliding platform to a position far away from the launching body.

Furthermore, the launching body comprises a driving component, a transmission part is arranged on the linkage part, the input end of the transmission part is connected with the driving component, the output end of the transmission part is connected with the launched object installed on the linkage part, and the driving component drives the launched object to store energy in a power mode when being driven.

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

the launching body is connected with the linkage piece, the linkage piece can drive the launched object to move from the assembling position to the launching position, and the launched object is launched out through the linkage piece. The invention realizes linkage emission of the emitted object through the linkage piece instead of monotonous emission of the emitted object from the emitting device, increases linkage play methods of the linkage piece, combines multiple play methods, and effectively improves the operability, playability and interestingness of the emitting device.

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 member of a linked multi-play launching device in a first state according to a first embodiment of the present invention;

fig. 2 is a schematic view of a linkage member of a linked multi-play launching device in a second state according to a first embodiment of the invention;

fig. 3 is an omitted view of a linkage member of the linkage multi-play launching device in a second state according to the first embodiment of the present invention;

FIG. 4 is a schematic view of a linkage member in a second state according to one embodiment of the present invention;

FIG. 5 is a schematic diagram of the internal structure of the linkage member in the second state according to the first embodiment of the present invention;

FIG. 6 is an enlarged partial view of a first linkage gear in accordance with one embodiment of the present invention;

FIG. 7 is a schematic view of a first linkage gear inserted into a torso portion in accordance with a first embodiment of the present invention;

FIG. 8 is a schematic diagram of the internal structure of the linkage member in the first state according to the first embodiment of the present invention;

FIG. 9 is a cross-sectional view of a head portion of a linkage member in accordance with one embodiment of the present invention;

FIG. 10 is an enlarged view of a portion of a linkage member in accordance with one embodiment of the present invention;

FIG. 11 is an enlarged view of a portion of the interior of the head according to one embodiment of the present invention;

FIG. 12 is an enlarged partial view of the internal structure of the accelerating assembly in accordance with one embodiment of the present invention;

FIG. 13 is an enlarged view of a portion of the internal structure of the launching body with the accelerating assembly lifted upwardly in accordance with one embodiment of the present invention;

FIG. 14 is an enlarged view of a portion of the internal structure of the emitter body with the acceleration assembly attached to the head according to one embodiment of the present invention;

fig. 15 is a schematic view of an initial state of the linked multi-play launching device according to the second embodiment of the present invention;

fig. 16 is a schematic view of a push handle of the linked multi-play launching device according to a second embodiment of the present invention when pushed backwards;

fig. 17 is a schematic view of an initial stage of forward pushing of the push handle of the linked multi-play launching device in accordance with the second embodiment of the present invention;

fig. 18 is a schematic view of the push handle of the linked multi-play launching device of the second embodiment of the present invention pushing forward to the bottom;

fig. 19 is a schematic view of a trigger of a linked multi-play launching device according to a second embodiment of the present invention;

fig. 20 is an internal structural view of an initial state of the linked multi-play launching device according to the second embodiment of the present invention;

fig. 21 is a schematic view of the internal structure of the linkage multi-play launching device according to the second embodiment of the present invention when the pushing handle is pushed backward;

fig. 22 is an internal structural view of an initial stage of forward pushing of the push handle of the linked multi-play launching device according to the second embodiment of the present invention;

fig. 23 is a schematic view of the internal structure of the push handle of the linked multi-play launching device according to the second embodiment of the present invention;

fig. 24 is a schematic view showing an internal structure of a trigger of the linked multi-play launching device according to the second embodiment of the present invention;

fig. 25 is an exploded view of the clip, cartridge and frame;

figure 26 is an exploded view of the clip and cartridge;

FIG. 27 is a perspective view of a linkage;

fig. 28 is a perspective view of the gun body;

FIG. 29 is a schematic view of a side of the clip striking assembly;

FIG. 30 is a schematic view of another side of the clip striking assembly;

FIG. 31 is a schematic view of the slider engaged with the foot;

FIG. 32 is a schematic view of the cocking mechanism, air cylinder and air cylinder lock in cooperation;

FIG. 33 is a schematic view of the trigger, cylinder lock and cylinder rod being engaged;

FIG. 34 is a schematic view of the engagement of the cylinder lock with the cylinder rod;

FIG. 35 is an internal schematic view of the linkage;

FIG. 36 is a schematic view of the glide and clip striking assembly;

FIG. 37 is a schematic view of the foot engaging the linkage locking assembly;

FIG. 38 is a schematic view of the catch spring assembly, foot and linkage locking assembly;

fig. 39 is a schematic view of a hook spring assembly.

In fig. 1-14:

emission body 01: the device comprises an accelerating component 011, a trigger 012, a launching slot 013, a rear-pressing buckle 014, a second lock latch 015, a limit block 016, a sliding groove 017, a handle 018, a bolt 0111, a pull ring 0112, an energy accumulator 0113, a transmission gear set 0114, an accelerating shell 0115, a limit slot 01151 and a toggle block 01152;

the linkage 02: arm 020, head 021, trunk 022, tail 023, linkage gear set 024, occlusal tooth 025, unidirectional face gear 026, first lock 027, first magnetic element 028, leg 029, foot 030, maxilla 0211, mandible 0212, transmission gear 0213, brake block 0221, first linkage gear 0241, second linkage gear 0242, third linkage gear 0243, occlusal slot 0251, tooth body 0252, brake stop wheel 0253;

the top toy 03: a second magnetic element 031.

In fig. 15-39:

cartridge clip 1: bullet 11, cylindrical through hole 12, bullet nest 13 and bullet through hole 111;

a gun body 2: the trigger 21, the clip slot 22, the clip button 23, the trip button 24, the ejection hole 25 and the linkage rod 26;

the launching mechanism 3: the air cylinder 31, the air pipe 32, the air nozzle 33, the air cylinder rod 311, the pressure spring 312 and the lock hole 3111;

the linkage 4: mouth 41, tail 42, foot 43, rotating shaft 44, cylinder 45, connecting air pipe 46 and bolt 451;

the loading mechanism 5: the elastic clip comprises a push handle 51, an elastic clip toggle assembly 52, a sliding member 53, a linkage member locking assembly 54, an elastic hooking assembly 55, a first rack 56, a transition gear 57, a second rack 58, a toggle block 521, a ratchet 522, a pin 523, a sliding groove 531, an inclined surface 532, a locking groove 541, a pull rope 551, a telescopic hook 552, an unlocking part 553, an insertion rod 5521, a tension spring 5522 and a hook part 5523;

an air cylinder locking member 6.

Detailed Description

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

It is easily understood that according to the technical solution of the present invention, those skilled in the art can substitute various structures and implementation manners without changing the spirit of the present invention. Therefore, the following detailed description and the accompanying drawings are merely illustrative of the technical aspects of the present invention, and should not be construed as limiting or restricting the technical aspects 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 one embodiment of the invention, the linkage multi-play launching device comprises a launching body, a linkage piece and a launched object;

the linkage piece is arranged outside the launching body;

the launched object is detachably mounted on the linkage piece, and the linkage piece can drive the launched object to move from the assembling position to the launching position on the launching body;

when the launched object is in the launching position and the trigger of the launching body is pulled, the launched object is launched.

Specifically, the launching body can be gun-shaped; the linkage piece can be an animal model, an airplane model, an automobile model or the like, which has a model body obviously different from the model of the launching body; the launched object can be a bullet, a top, a toy car, a flying disc and the like.

In some embodiments of the invention, the linkage is capable of sliding, or swinging, between an assembly position and a firing position on the firing body.

For example: the linkage piece can slide along the straight line back and forth along the length direction of transmission body, or rotatable coupling between linkage piece and the transmission body, and the linkage piece can rotate forward for the transmission body, or rotate backward. The front end of the launching body can be an assembly position, and the rear end can be a launching position.

Of course, the movement of the linkage member is not limited to sliding or swinging, and may be, for example, both sliding and swinging, that is, the linkage member may also swing left and right or back and forth during the sliding process between the assembling position and the launching position; in addition, the movement modes such as jumping, rotating and moving can be adopted.

The object to be launched can be driven to approach to the launching position together through the movement or the swing of the linkage piece, and the object to be launched can be launched out through pulling the trigger after being taken to the launching mechanism of the launching body.

In some embodiments of the invention, the projectile is mounted directly into the linkage.

For example: the projectile may be manually mounted directly into a linkage by the player, which itself locks the projectile.

In some embodiments of the invention, the launching body comprises a hook spring assembly, and the launched object is brought into the linkage piece through the hook spring assembly.

For example: the bullet hooking component is pulled through operation, and drives the launched object to enter the linkage piece.

In some embodiments of the invention, the device further comprises a storage piece, a plurality of launched objects are arranged in the storage piece, and the storage piece is detachably arranged in the launching body;

the bullet hooking component is used for driving one shot object in the storage object to enter the linkage part.

Specifically, the storage part can be a cartridge clip, a plurality of launched objects can be loaded into the storage part, and the plurality of launched objects can be continuously launched.

The bullet hooking component drives one shot object in the storage object to enter the linkage part, and the linkage part drives the shot object to the shooting mechanism of the shooting body, so that the shot object is loaded.

In some embodiments of the present invention, the launching body includes an operating component, and the operating component is used for driving the linkage member to slide or swing.

For example: the operating component can drive the linkage piece to move forwards or backwards along the launching body. When forward, be convenient for pack into the linkage with the thing of being launched in, be used for being connected the linkage with the firing mechanism or the subassembly with higher speed of launching the body when backward, realize energy storage or accelerate, after pulling the trigger, will launch the thing by the shooting.

In some embodiments of the invention, a locking piece for locking the linkage piece in a launching state is arranged in the launching body, the locking piece is linked with the trigger, the linkage piece is provided with an elastic 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 launched object is triggered to be launched when moving through the linkage piece.

For example: the second locker 015 in the first embodiment can lock the link 02 at the striking position of the rear end of the striking body 01.

The trigger drives the locking piece to unlock the linkage piece, the elastic piece drives the linkage piece to move forwards, the launched object moves forwards along with the linkage piece, when the linkage piece moves to the foremost end of the launching body, the linkage piece is stopped by limiting and moves, the launched object is separated from the linkage piece, and the launched object is launched.

In some embodiments of the invention, the launching body is internally provided with a launching part used for launching the launched object away from the linkage part, and the launching part is linked with the trigger;

when the trigger is pulled down, the launching piece drives the launched object to be launched.

Optionally, only the launched object is launched, the linkage piece is not moved, and the linkage piece can only be driven by the operating piece to move back and forth.

In some embodiments of the invention, the following can also be designed: when the trigger is pulled down, the launching piece drives the launched object to be launched, and the launched object triggers the linkage piece to move when leaving the linkage piece.

In some embodiments of the present invention, the linkage member is provided with a locking member, and when the launched object leaves the linkage member, the launched object triggers the locking member to unlock so as to enable the linkage member to move, namely, the motion, including but not limited to deformation, movement, swing and jumping.

In other embodiments of the invention, the launching body is internally provided with a launching part for launching the launched object away from the linkage part, and the launching part is linked with the trigger; the trigger is also provided with a locking piece used for locking the linkage piece in a launching state, the locking piece is linked with the trigger, and the linkage piece is provided with an elastic piece which stores energy when in a launching position; when the trigger is pulled down, the locking piece can be triggered to unlock, the elastic piece drives the linkage piece to move from the launching position to the assembling position, and the launching piece is triggered to launch the launched object.

When the linkage piece and the launched object are launched simultaneously, the linkage piece can move forwards until the front end of the launching body, and the launched object is separated from the linkage piece subsequently and continuously flies out.

In some embodiments of the invention, the linkage comprises a movable member, the linkage being configured in a first configuration when the movable member is in a first position, the linkage being configured in a second configuration when the movable member is in a second position;

when the trigger is pulled, the trigger linkage is deformed from the first configuration to the second configuration.

The trigger can trigger the linkage piece to deform, and the linkage piece can trigger the launched object to launch or be separated from the launched object after being deformed.

The deformation of the linkage piece can bring the change of the shape and increase the interest of the toy.

In some embodiments of the invention, the firing body further comprises a sliding platform, the linkage member is slidably connected to the sliding platform, and when the trigger is pulled down, the linkage member moves from one end of the sliding platform to the other end; or the sliding platform moves to a position far away from the shooting body, and the linkage piece can be separated from the shooting body like a bullet to be shot.

For example: in the first embodiment, the sliding groove 017 is a sliding platform, and the link 02 slides back and forth along the sliding groove 017.

Alternatively, the sliding platform may be a sliding rail, the linkage may be a vehicle, and the object to be launched may be a rocket mounted on the vehicle.

When the trigger is pulled, the scooter and the rocket can be launched out simultaneously, the scooter slides forwards along the slide rail, and the rocket is triggered to be launched out after the scooter is launched or slides to a certain stage.

In some embodiments of the invention, the firing body further comprises a locking member for locking the linkage at the front or rear end of the firing body.

For example: the second locking buckles 015 in the first embodiment can lock the link 02 at the rear end of the transmitting body 01.

The link locking assembly 54 in the second embodiment is capable of locking the link 4 at the front end of the gun body 2 (firing body).

In some embodiments of the invention, the launching body comprises a driving component, the linkage member is provided with a transmission member, the input end of the transmission member is connected with the driving component, the output end of the transmission member is connected with the launched object mounted on the linkage member, and the driving component drives the launched object to store energy in a power manner when being driven.

The driving assembly can be the accelerating assembly 011 or the pull rope assembly in the first embodiment, the driven launching piece is driven to store energy by repeatedly pulling the pull rope, and after the trigger is pulled, the driven launching piece is launched and falls on the ground to continue driving or rotating.

The driving assembly can also be a pull handle assembly, and the driven piece is driven to store energy by repeatedly pulling the pull handle.

When the object to be launched is a gyroscope, the driving component can drive the gyroscope to rotate; when the launched object is a vehicle, the driving assembly can drive an inertia wheel in the vehicle to rotate; when the launched object is a pneumatic toy, the driving assembly can store air for the pneumatic toy.

The first embodiment is as follows:

fig. 1 to 14 are schematic views of a linked multi-play launching device according to a first embodiment.

In the first embodiment, the top toy 03 is a launched object.

As shown in fig. 1, the linkage multi-play launching device comprises a launching body 01, a linkage member 02 and a top toy 03, wherein the linkage member 02 can move back and forth on the launching body 1, and the linkage member 02 at least comprises a first state and a second state;

in the first state, the linkage member 02 is unfolded and positioned at the front end of the launching body 01, and the top toy 03 is connected with the linkage member 02;

in the second state, the linkage 02 is folded and deformed and slides to the rear end of the launching body 01 to be connected with the accelerating assembly 011, and the accelerating assembly 011 accelerates the top toy 03 through the linkage 02;

after the trigger 012 of the launching body 1 is pulled, the launching body 01 ejects the linkage 02 forward and unfolds to the first state, and the top toy 03 is launched from the linkage 02.

Specifically, as shown in fig. 1, the link 02 is in the first state. At this time, the link 02 is positioned at the foremost end (left side in fig. 1) of the launching body 01, and each part of the link 02 is unfolded into a dinosaur shape, and the mouth of the dinosaur shape is opened, so that the top toy 03 can be put therein.

As shown in fig. 2, the link 02 is in the second state. The link 02 slides backward (right side of fig. 1), and during the sliding, the rotational deformation is folded into the rear end of the emitting body 01. The mouth of the dinosaur-shaped toy is closed, and the top toy 03 is clamped in the mouth. The linkage 02 is connected with the accelerating assembly 011 at the moment, the accelerating assembly 011 is positioned above the linkage 02, and the top toy 03 is accelerated through the transmission of the linkage 02.

After the top toy 03 is accelerated to a certain speed, the trigger 012 is pulled, the trigger 012 releases the acceleration assembly 011, so that the acceleration assembly 011 is separated from the linkage 02, meanwhile, the trigger 012 also releases the linkage 02, the linkage 02 is ejected forwards under the action of the tension spring, and in the ejection process, all parts of the linkage 02 rotate and are unfolded to the first state. The top toy 03 and the linkage 02 are separated at this time, and fall on the ground or a game table to keep rotating for a certain time.

The linkage 02 in this embodiment can drive the top toy 3 to the accelerating assembly 011 of the launching body 01, and realizes acceleration of the top toy 03. By pulling the trigger 012, the launching of the toy gyroscope 03 is realized by the linkage with the trigger 012. And linkage 02 can switch to the second state from the first state, switches to the first state from the second state again, has increased linkage many methods of playing emitter's playability and interest to novel structure has increased the appeal to children.

Alternatively, the linkage 02 is not limited to a 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.

In this embodiment, the firing body 01 is gun-shaped, the firing body 01 includes a sliding groove 017, a firing slot 013, and a handle 018, and a trigger 012 is installed at the handle 018. The link 02 can slide back and forth along the sliding groove 017 and enter the launching slot 013 when sliding back.

Further, as shown in fig. 1, the link 02 is of an animal shape, the link 02 includes a head part 021, a trunk part 022 and a tail part 023, the toy top 03 is connected to the head part 021, and when the link 02 moves backward to be connected to the acceleration assembly of the launching body 01, the head part 021, the trunk part 022 and the tail part 023 are rotatably folded and received in the launching slot 013 of the launching body 01.

Specifically, as shown in fig. 1, in the first state, the head part 021, the trunk part 022 and the tail part 023 are unfolded to have a dinosaur shape.

As shown in fig. 3-4, in the second state, the trunk portion 022 rotates clockwise with respect to the head portion 021 until the trunk portion 022 collides with the head portion 021 and cannot rotate any further, and the head portion 021 and the trunk portion 022 are in a mutually perpendicular state. The tail portions 023 are rotated clockwise relative to the trunk portion 022 and received in the bottom, and the tail portions 023 are substantially perpendicular to the trunk portion 022.

As shown in fig. 1, the linkage 02 further includes a leg portion 029 and a foot portion 030, the leg portion 029 and the body portion 022 are rotatably connected through a torsion spring and a rotation shaft, and the leg portion 029 and the foot portion 030 are rotatably connected through a torsion spring and a rotation shaft.

As shown in fig. 3, in the second state, the leg portion 029 and the foot portion 030 are also rotated clockwise and accommodated in a state substantially perpendicular to the body portion 022. At this time, the interlocking member 02 is substantially a cube and can be received in the launching groove 013 (see fig. 1) of the launching body 01.

Further, as shown in fig. 4, the head 021 includes an upper jaw 0211 and a lower jaw 0212, and the top toy 03 is attached to the upper jaw 0211 and is located between the upper jaw 0211 and the lower jaw 0212;

the linkage 02 moves forward backward, the upper jaw 0211 and the lower jaw 0212 open;

when the link 02 moves backward to be connected with the accelerating assembly 011 of the launching body 01, the lower jaw 0212 rotates upward to hold the lower portion of the top toy 03.

Specifically, as shown in fig. 8, in the first state, the upper jaw 0211 and the lower jaw 0212 are opened, the upper jaw 0211 and the lower jaw 0212 are rotatably connected, and a torsion spring (not shown) is installed at the rotating position.

During the second state, linkage piece 02 rotates foldingly, and linkage piece 02's arm 020 is connected with trunk 022, and during trunk 022 clockwise rotation, drive arm 020 and also rotate clockwise together, and arm 020 rotates to when contradicting with chin 0212, drives chin 0212 and upwards rotates together for chin 0212 rotates towards the direction of palace 0211, realizes the closure of the figurative mouth of dinosaur.

As shown in fig. 2, after the mouth of the dragon is closed, the lower jaw 0212 restrains the top toy 03 therein, but the lower jaw 0212 does not affect the rotation of the top toy 03 at the time of acceleration.

Further, as shown in fig. 5, a linkage gear set 024 is disposed inside the head part 021, the trunk part 022 and the tail part 023, and when the head part 021 is pressed downwards, the linkage gear set 024 is driven to rotate, and the linkage gear set 024 drives the trunk part 022 and the tail part 023 to rotate and fold.

Specifically, as shown in fig. 6, the linkage gear set 024 includes a first linkage gear 0241, the first linkage gear 0241 is fixedly connected to the upper jaw 0211, and when the head 021 is pressed downward, the upper jaw 0211 drives the first linkage gear 0241 to rotate together.

As shown in fig. 7, when mounted, the first link gear 0241 is inserted into the trunk portion 022.

As shown in fig. 5, the linkage gear set 024 further includes a second linkage gear 0242, the second linkage gear 0242 being provided in the trunk portion 022, the second linkage gear 0242 being meshed with the first linkage gear 0241. When the first linkage gear 0241 is driven by the head 021, the second linkage gear 0242 is driven to rotate together.

As shown in fig. 5 and 8, the linkage gear set 024 further includes a third linkage gear 0243, and the third linkage gear 0243 is provided in the tail portion 023 and is fixedly connected with the tail portion 023. The second linkage gear 0242 drives the third linkage gear 0243 to rotate, so that the third linkage gear 0243 drives the tail 023 to rotate to a second state and is collected into the bottom of the trunk 022.

In this embodiment, the head part 021, the trunk part 022 and the tail part 023 are rotatably connected through torsion springs. In the first state, when the head part 021 is pressed down and back, the folding of the tail part 023 is realized by the linkage gear set 024. The head part 021 rotates counterclockwise downwards towards the trunk part 022 until the head part 021 collides with the trunk part 022, then the head part 021 and the trunk part 022 rotate clockwise relative to the leg parts 029 and the foot parts 030 together, and the leg parts 029 and the foot parts 030 are pushed to rotate clockwise, so that the dinosaur-shaped linkage member 02 rotates and is folded to the second state.

When the linkage 02 is released by the trigger 012, the linkage 02 returns to the first state under the action of the torsion springs at the respective rotational connections. At this time, the linkage gear set 024 is driven to rotate reversely.

Further, as shown in fig. 10-11 and 13-14, the head 021 is provided with engaging teeth 025, and the emission body 01 is provided with a rear pressure release button 014;

before the linkage 02 moves backwards, the accelerating component 011 is lifted upwards, and the rear release buckle 14 extends forwards;

when the linkage 02 moves backwards to be connected with the accelerating component 011 of the launching body 01, the head 021 presses the rear pressing release buckle 014, the rear pressing release buckle 014 drives the accelerating component 011 to downwards mesh with the meshing teeth 025, and the accelerating component 011 drives the top toy 03 to accelerate through the meshing teeth 025;

the trigger 012 is linked to the accelerating assembly 011, and when the trigger 012 is pulled, the accelerating assembly 011 is again lifted upward and separated from the teeth 025.

Specifically, as shown in fig. 13, the accelerating assembly 011 is lifted upward by the torsion spring of the accelerating assembly 011, and the latch 0111 of the accelerating assembly 011 is separated from the engaging teeth 025. The accelerating assembly 011 extends downwards to form a toggle block 01152, and when the accelerating assembly 011 is lifted upwards, the toggle block 01152 toggles the rear release button 014 forwards, so that at least part of the rear release button 014 extends out of the casing of the launching body 01.

The acceleration assembly 011 further comprises an acceleration housing 0115, and the acceleration housing 0115 is provided with a limit groove 01151. The trigger 012 is linked with the limit block 016. When the accelerating component 011 is lifted upwards, the limiting block 016 is separated from the limiting groove 01151.

As shown in fig. 14, when the linkage 02 moves backward, the head 021 presses the rear release button 014, the rear release button 014 retracts into the casing of the launching body 01, and the toggle block 01152 is toggled to the right, and the toggle block 01152 drives the accelerating assembly 011 to rotate downward, so that the latch 0111 of the accelerating assembly 011 is inserted into the meshing tooth 025.

After the accelerating component 011 rotates downwards, the limiting block 016 is inserted into the limiting groove 01151 to keep the accelerating component 011 at the position of connecting and driving with the meshing teeth 025. The acceleration assembly 011 can accelerate the top toy 03 through the teeth 025.

When the top toy 03 is accelerated to a certain speed, the trigger 012 is pulled, the trigger 012 moves backwards, and the limiting block 016 is pushed to move backwards, the limiting block 016 is separated from the limiting groove 01151, and the accelerating component 011 is lifted upwards under the action of the torsion spring of the accelerating component, and is separated from the meshing teeth 025.

In this embodiment, as shown in fig. 12-13, the acceleration assembly 011 further includes a pull ring 0112, an accumulator 0113, and a drive gear set 0114.

The energy accumulator 0113 and the transmission gear set 0114 are mounted in an acceleration housing 0115, and the tab 0112 is located outside the acceleration housing 0115. One end of a pull rope (not shown) is connected to the pull ring 0112, and the other end of the pull rope is connected to the energy accumulator 0113.

During acceleration, pull ring 0112 is pulled back to drive energy accumulator 0113 to accumulate energy, energy accumulator 0113 drives transmission gear set 0114 to rotate, transmission gear set 0114 drives bolt 0111 to rotate, and bolt 0111 drives meshing tooth 025 to rotate.

Further, as shown in fig. 10, a brake block 0221 is arranged on the trunk portion 022, when the linkage member 02 is ejected forward, the head portion 021, the trunk portion 022 and the tail portion 023 rotate to unfold, and the trunk portion 022 drives the brake block 0221 to bump into the stopping occlusion teeth 025.

Specifically, the brake pad 0221 is disposed at the neck of the body portion 022, extending from the junction of the body portion 022 and the head portion 021, and extending into the shell of the head portion 021.

When the acceleration assembly 011 accelerates the top toy 03, the engagement teeth 025 are driven to rotate, and after the trigger 012 is pulled, the linkage 02 is released, so that the head part 021, the body part 022 and the tail part 023 are rotated and unfolded to a first state. In the unfolding process, the brake block 0221 bumps the meshing teeth 025 to stop rotating, at the moment, the spinning top toy 03 continues to rotate under the action of inertia and is separated from the meshing teeth 025 to be linked, and the spinning top toy 03 falls onto the ground or a game platform to continue to rotate and play.

Further, as shown in fig. 10-11, the engagement teeth 025 include an engagement slot 0251, a tooth body 0252 and a brake stop wheel 0253, the engagement slot 0251 is located on the top surface of the head portion 021, the plug pin 0111 of the acceleration assembly 011 is inserted into the engagement slot 0251, the tooth body 0252 is linked with the one-way face gear 026, and the one-way face gear 026 drives the top toy 03 to rotate at an accelerated speed. When the brake block 0221 is abutted against the brake wheel 0253, the engaging teeth 025 stop rotating, so that the unidirectional face gear 026 stops rotating, and the spinning top toy 03 is separated from the unidirectional face gear 026.

The engagement slot 0251 is positioned on the top surface of the head part 021, so that the plug pin 0111 of the acceleration assembly 011 can be inserted into the engagement slot 0251 conveniently; the tooth body 0252 is positioned below the occlusion slot 0251 and is in transmission connection with the one-way face gear 026 through a transmission gear 0213; the brake wheel 0253 is located at the bottom of the tooth body 0252, and the brake wheel 0253 includes four gear teeth, and when one of the gear teeth interferes with the brake pad 0221, the rotation of the meshing tooth 025 is stopped, so that the transmission gear 0213 and the one-way face gear 026 are also stopped.

As shown in figure 4, a single-sided gear 026 is exposed from the bottom of the upper jaw 0211 for engagement with a top toy 03.

As shown in figure 8, a plurality of unidirectional face teeth are provided on unidirectional face gear 026, and corresponding teeth that mesh with the unidirectional face teeth are provided on top toy 03. The unidirectional face gear 026 can only drive the top toy 03 to rotate in one direction. When the unidirectional face gear 026 stops rotating, the top toy 03 continues to rotate under the action of inertia, and the inclined surface of the unidirectional face teeth pushes the top toy 03 downwards, so that the top toy 03 is separated from the unidirectional face gear 026 and falls onto the ground or a game table.

Further, as shown in fig. 3 to 5, the linkage member 2 is provided with a first lock button 027, and the launching body 01 is provided with a second lock button 015;

when the link 02 moves backward, it is held at the rear end of the transmitting body 01 by the locking of the first locker 027 with the second locker 015;

the trigger 012 is linked with the second lock button 015, and after the trigger 012 is pulled, the second lock button 015 is unlocked with the first lock button 027.

Specifically, the first lock 027 is disposed at the bottom of the foot 030, the foot 030 is rotatably connected to the first lock 027, and the first lock 027 can slide back and forth along the sliding groove 017 of the launching body 1.

When the link 02 moves backward to connect with the accelerating assembly 011, the first catches 027 slide to a position locked with the second catches 015, holding the link 02 in that position.

The second hasp 015 sets up in the casing of transmission body 01, and second hasp 015 and trigger 012 linkage when trigger 012 is detained, drive second hasp 015 rearward movement for second hasp 015 and first hasp 027 separate. The first lock buckle 027 is connected with a tension spring, and the linkage member 02 is ejected forwards under the action of the tension spring and slides to the foremost end of the launching body 01 quickly.

Further, as shown in fig. 9, a first magnetic element 028 is provided in the link 02, a second magnetic element 031 is provided in the top toy 03, and the top toy 03 is attracted to the link 02 by the attraction between the first magnetic element 028 and the second magnetic element 031.

Specifically, the first magnetic element 028 is disposed inside the unidirectional face gear 026, and when the top toy 03 is placed in the head 021, the first magnetic element 028 and the second magnetic element 031 attract each other, so that the top toy 03 can be rapidly engaged with the unidirectional face gear 026.

When the unidirectional face gear 026 stops rotating, top toy 03 continues to rotate, and the inclined plane of the unidirectional face tooth pushes the top toy 03 downwards, so that the top toy 03 is separated from the unidirectional face gear 026, the magnetic force between the first magnetic element 028 and the second magnetic element 031 is not enough to adsorb the top toy 03, and the top toy 03 falls onto the ground or a game table.

One play method of the linkage multi-play-method transmitting device in the embodiment is as follows:

as shown in figure 1, with linkage 02 in the first position, top toy 03 is placed in the mouth of the dinosaur figure, with top toy 03 engaged with one-way face gear 026.

Then, the head 021 is pushed downward and rearward, the link 02 is rotationally folded to the second state of fig. 2, and locked in the shooting slot 013. At this point, the accelerating assembly 011 tips downward, engaging the teeth 025 in the head 021.

And rapidly pulling back a pull ring 0112 of the pulling acceleration assembly 011 to accelerate the top toy 03.

When accelerating to a desired speed, trigger 012 is pulled, and trigger 012 unlocks linkage 02, releasing acceleration assembly 011 to lift upward and separate from linkage 02. The linkage member 02 is rapidly ejected forwards under the action of the tension spring, and in the ejecting process, the linkage member 02 is unfolded from the second state to the first state. When the top toy 03 is unfolded to the second state, the top toy 03 is separated from the linkage member 02, and the top toy 03 falls on the ground or a game table and keeps rotating for a certain time.

The deformation linkage piece can be unfolded and deformed into an animal shape while launching the top toy, so that the interest and the playability of the toy are improved.

Example two:

fig. 15 to 39 are schematic views of a linked multi-play launching device according to a second embodiment.

In the second embodiment, the cartridge holder 1 is a storage object, the gun body 2 is a shooting body, the loading structure 5 is an operating element, and the bullet 11 is a shot object.

As shown in fig. 15, the linked multi-play launching device comprises a cartridge holder 1 and a gun body 2, wherein the cartridge holder 1 is detachably connected to the gun body 2, a plurality of bullets 11 (see fig. 25) can be loaded in the cartridge holder 1, a trigger 21 and a launching mechanism 3 (see fig. 20) are arranged on the gun body 2, the linked multi-play launching device further comprises a linkage 4, and a loading mechanism 5 is arranged on the gun body 2;

the loading mechanism 5 is used for driving the linkage piece 4 to the side of the cartridge clip 1, then pushing a bullet 11 in the cartridge clip 1 into the linkage piece 4, and then releasing the linkage piece 4 by the loading mechanism 5 so as to enable the linkage piece 4 to move and be connected with the launching mechanism 3;

when the trigger 21 is pulled, the trigger 21 triggers the firing mechanism 3 to fire the cartridge 11 in the linkage 4.

In this embodiment, the linkage 4 is shaped like a dinosaur, the cartridge holder 1 is disposed at the front end of the gun body 2 (i.e., the left side of fig. 15), and the firing mechanism 3 is disposed at the rear end of the gun body 2 (i.e., the right side of fig. 15).

Fig. 15 shows an initial state of the linked multi-play launching device, in which the linkage member 4 is located at the rear end of the gun body 2 and connected to the launching mechanism 3 installed inside the gun body 2.

The cartridge holder 1 is detachably connected to the frame 2, and the cartridge holder 1 is mounted in the frame 2 in fig. 15.

As shown in fig. 16, the link 4 is moved by the loading mechanism 5 in the direction of the cartridge holder 1, so that the link 4 receives a cartridge 11 in the cartridge holder 1.

As shown in fig. 17, the cocking mechanism 5 pushes one cartridge 11 of the cartridge holder 1 into the linkage 4.

As shown in fig. 18, the cocking mechanism 5 releases the link 4 so that the link 4 returns to the position of connection with the firing mechanism 3.

As shown in fig. 19, the trigger 21 is pulled and the firing mechanism 3 fires the cartridge 11 in the link 4.

In this embodiment, the linkage member 4 is driven by the loading mechanism 5, and a bullet 11 is pushed into the linkage member 4, so that the shooting mechanism 3 shoots the bullet 11 through the linkage member 4, thereby increasing the playability and the interest of the toy gun. And the linkage piece 4 is in an animal shape, so that the appearance of the toy gun is more vivid and interesting, and the attraction to children is increased.

Alternatively, the linkage 4 may be in the form of another animal model, or an automobile model, or an airplane model.

Further, as shown in fig. 25, a cartridge slot 22 is provided at the front end of the gun body 2, a cartridge clip 23 and a release button 24 are provided in the cartridge slot 22, the cartridge clip 23 locks the cartridge clip 1 after the cartridge clip 1 is inserted into the cartridge slot 22, and the release button 24 is used to unlock the cartridge clip 1.

Specifically, the clip 23 is controlled by the release button 24, and when the release button 24 is pressed, the clip 23 retracts, and the clip 1 is released and can be removed from the gun body 2.

When the release button 24 is released, the clip 23 extends into, locking the clip 1 in the clip slot 22 of the body 2.

Further, as shown in fig. 25, a hexagonal cylindrical through hole 12 is formed in the cartridge holder 1, the trip button 24 is a hexagonal cylinder, and the trip button 234 is inserted into the cylindrical through hole 12 of the cartridge holder 1 for driving the cartridge holder 1 to rotate.

Specifically, the trip button 234 is disposed at the center of the clip slot 22 and protrudes outward. The spring clips 23 extend radially outward from the trip button 234, and there may be one, two, or more spring clips 23.

After the release button 234 is inserted into the cylindrical through hole 12 of the cartridge clip 1, the cartridge clip 23 tightly pushes the inner wall of the cartridge clip 1 to prevent the cartridge clip 1 from falling off.

As shown in fig. 26, the cartridge holder 1 is cylindrical and comprises a plurality of cartridges 13, each cartridge 13 being capable of holding a cartridge 11.

The bullet 11 in this embodiment is a soft bullet made of foam, and is loaded into the bullet nest 13 and is in interference fit with the bullet nest 13.

The cartridge 11 is provided with a cartridge opening 111 for easy insertion into the link 4.

As shown in fig. 27, the interlocking member 4 is provided with a barrel 45, the barrel 45 is positioned inside the mouth 41, and the barrel 45 is provided with a latch 451. When the cartridge 11 is pushed into the barrel 45, the latch 451 is inserted into the shot hole 111 and interference fit so that the cartridge 11 can be held in the linkage 4.

Further, as shown in fig. 20 and 29, the loading mechanism 5 includes a push handle 51 and a clip moving assembly 52, the push handle 51 can slide along the gun body 2, when the push handle 51 slides towards one side, the clip moving assembly 52 is driven, the clip moving assembly 52 drives the clip 1 to rotate one cell through the trip button 24, and each cell corresponds to one bullet 11.

Specifically, as shown in fig. 36, the charging mechanism 5 further includes a sliding member 53, the push handle 51 is fixedly connected to the sliding member 53, and the push handle 51 can slide back and forth along the gun body 2.

As shown in fig. 29, the sliding member 53 is provided with a sliding slot 531, and the sliding slot 531 can drive the clip striking assembly 52 to move in the initial state.

Specifically, as shown in fig. 29, the clip moving assembly 52 includes a moving block 521, a ratchet 522 and a pin 523, the pin 523 is inserted into a sliding slot 531 in the initial state of fig. 15, when the push handle 51 drives the sliding member 53 to move backward, the sliding slot 531 of the sliding member 53 drives the pin 523 backward, the pin 523 drives the moving block 521 to move backward, the moving block 521 moves the ratchet 522, the ratchet 522 is installed at the rear end of the trip key 24, the push handle 51 drives the moving block 521 to rotate once, the moving block 521 moves the ratchet 522 to rotate one tooth, the ratchet 522 drives the trip key 24 to rotate, and the trip key 24 drives the clip 1 to rotate one grid.

The clip 1 is rotated one by the push handle 51 to rotate the cartridge 11 in one of the magazine 13 to a position ready for entering the linkage 4.

As shown in fig. 28, the gun body 2 is provided with ejection holes 25, and one of the cartridge nests 13 is aligned with the ejection hole 25 every time the cartridge holder 1 rotates one rotation.

When the linkage 4 is moved towards one side of the cartridge holder 1, the linkage 4 is also aligned with the ejection aperture 25, facilitating subsequent pushing of the cartridge 11 into the linkage 4.

Further, as shown in fig. 31, the linkage member 4 is rotatably connected to the gun body 2, the loading mechanism 5 includes a pushing handle 51 and a sliding member 53, the pushing handle 51 slides along the gun body 2, the pushing handle 51 is fixedly connected to the sliding member 53, when the pushing handle 51 slides to one side, the sliding member 53 is driven to slide, and the sliding member 53 pushes the linkage member 4 to turn toward one side of the cartridge clip 1.

Specifically, the sliding member 53 is provided with a slope 532, when the pushing handle 51 moves backwards, the slope 532 contacts with the foot 43 of the linkage member 4, the foot 43 is rotatably connected with the gun body 2 through the rotating shaft 44 (see fig. 27), and the slope 532 pushes the lower part of the foot 43, so that the linkage member 4 with the whole dinosaur shape rotates forwards towards the direction of the cartridge clip 1.

Optionally, a torsion spring is mounted at the rotation shaft 44, and when the linkage 4 rotates towards the direction of the cartridge holder 1, the torsion spring stores energy. When the push handle 51 is slid forward, the ramp 532 disengages from the foot 43 for releasing the linkage member 4, and the linkage member 4 returns to the initial position of fig. 15 under the action of the torsion spring, i.e., rotates backward to connect with the firing mechanism 3.

Alternatively, it is also possible to eliminate the torsion spring and add a ramp on the sliding member 53, which ramps the linkage member 4 backwards when the sliding member 53 slides forwards.

Further, as shown in fig. 21-22, the loading mechanism 5 comprises a push handle 51 and a bullet catch assembly 55, and when the push handle 51 slides towards one side, the bullet catch assembly 55 is inserted into one of the bullet nests 13 of the cartridge holder 1 from the gun body 2;

when the push handle 51 slides towards the other side, the bullet hooking component 55 is driven to hook the bullet 11 in the bullet nest 13 into the linkage 4.

Specifically, as shown in fig. 39, the hook spring assembly 55 includes a pull rope 551 and a telescopic hook 552, and the pull rope 551 is connected to the push handle 51. The telescopic hook 552 further includes an insertion rod 5521, a tension spring 5522, and a hook portion 5523, the pull rope 551 is connected to one end of the insertion rod 5521, the hook portion 5523 is rotatably connected to the other end of the insertion rod 5521, one end of the tension spring 5522 is connected to the middle section of the insertion rod 5521, and the other end is connected to the gun body 2.

As shown in fig. 21, when the push handle 51 slides backward, the pull rope 551 is released, the tension spring 5522 drives the insertion rod 5521 to extend into the clip slot 22, and the hook 5523 is folded and retracted into the insertion rod 5521 while the insertion rod 5521 passes through the clip slot 22. When the front end of the insertion rod 5521 passes through the clip groove 22, the hook 5523 is rotated to spread and extend into one of the cartridges 13 to contact the front end of the cartridge 11.

As shown in fig. 22, when the push plate 51 slides forward, the pull rope 551 is driven, the insertion rod 5521 is pulled backward by the pull rope 551, the hook portion 5523 drives a bullet 11 into the linkage member 4, i.e., the mouth 41 of the dinosaur, and the tension spring 5522 is charged.

Further, as shown in fig. 37 to 38, the loading mechanism 5 further includes a link locking assembly 54, and after the link 4 is turned toward the clip 1, the link locking assembly 54 locks the link 4;

when the push handle 51 is slid to the other side, the interlocking lock assembly 54 is unlocked, and the linkage 4 is released to flip over toward one side of the firing mechanism 3.

Specifically, as shown in fig. 37, the linkage locking assembly 54 further includes a lock groove 541, when the foot 43 of the linkage 4 is pushed backward by the inclined surface 532, the foot 43 is caught in the lock groove 541, and is locked at this position, so that the linkage 4 is kept in a forward-flipped state.

As shown in fig. 38, when the hooking spring assembly 55 retracts backward to hook the bullet 11 into the interlocking member 4, the unlocking portion 553 of the hooking spring assembly 55 strikes the interlocking lock assembly 54, so that the interlocking lock assembly 54 is disengaged from the foot 43. The foot 43 now, in the position of the return spring, drives the entire linkage 4 backwards, so that the linkage 4 is connected to the firing mechanism 3.

Further, as shown in fig. 20, the launching mechanism 3 includes an air cylinder 31, an air tube 32 and an air nozzle 33, the air cylinder 31 is communicated with the air nozzle 33 through the air tube 32;

when the linkage 4 is communicated with the air nozzle 33, the trigger 21 is pulled, and the air cylinder 31 blows air into the linkage 4 to launch the bullet 11 in the linkage 4.

Specifically, as shown in fig. 35, the linkage 4 is provided with a connecting air pipe 46 and a barrel 45, the connecting air pipe 46 communicates with the barrel 45, and an opening of the connecting air pipe 46 is opened from the tail portion 42.

When the linkage 4 is abutted against the air cock 33 of the shooting mechanism 3, the air of the air cylinder 31 passes through the air pipe 32, the air cock 33, the connecting air pipe 46 and the cartridge 45 in order to shoot the bullet 11.

Further, as shown in fig. 32, the loading mechanism 5 further includes a push handle 51, a first rack 56, a transition gear 57 and a second rack 58, the air cylinder 31 includes an air cylinder rod 311 and a compression spring 312, the push handle 51 can slide back and forth along the gun body 2, the push handle 51 is fixedly connected with the first rack 56, and the second rack 58 is fixedly connected with the air cylinder rod 311;

when the push handle 51 is pushed towards one side, the first rack 56 is driven to move, the first rack 56 drives the transition gear 57 to rotate in a single direction, the transition gear 57 drives the second rack 58 to move, and the second rack 58 drives the air cylinder rod 311 to overcome the chain winding of the pressure spring 312 and lock;

when the trigger 21 is pulled, the cylinder rod 311 is released, and the cylinder rod 311 presses the gas by the compression spring 312, and the gas is ejected from the gas nozzle 33.

Specifically, the first rack 56 is fixedly connected to the push handle 51, and the longitudinal direction of the first rack is arranged along the front-rear direction of the gun body 2, and the longitudinal direction of the second rack 58 is parallel to the first rack 56.

The transition gear 57 comprises two coaxially connected gears, a first rack 56 engaging one of the gears and a second rack 58 engaging the other gear. The first rack 56 can only drive the transition gear 57 in one direction, that is, when moving in one direction, the second rack 58 can be driven by the transition gear 57, and when moving in the other direction, the second rack 58 cannot be driven. The second rack 58 is integrated with the cylinder rod 311, and the cylinder rod 311 is inserted into the cylinder 31.

As shown in fig. 21, when the pushing handle 51 slides backwards, the first rack 56 is driven to move, the first rack 56 drives the transition gear 57 to rotate in one direction, the transition gear 57 drives the second rack 58 to move, and the second rack 58 drives the cylinder rod 311 to overcome the winding of the compression spring 312 and to be locked;

when the push handle 51 slides forward, the second rack 58 is not moved, and the position of the cylinder rod 311 remains unchanged.

As shown in fig. 24, when the trigger 21 is pulled, the trigger 21 releases the cylinder rod 311, and the cylinder rod 311 presses the gas by the compression spring 312 to be ejected from the gas nozzle 33.

Further, as shown in fig. 32-33, the linked multi-play launching device further comprises an air cylinder locking member 6, the air cylinder locking member 6 is linked with the trigger 21, and the air cylinder rod 311 is provided with a lock hole 3111;

when the cylinder rod 311 is brought to the cylinder lock 6 by the transition gear 57, the cylinder lock 6 is inserted into the lock hole 3111 to lock the cylinder rod 311;

when the trigger 21 is pulled, the trigger 21 brings the cylinder lock 6 to release the cylinder rod 311.

Specifically, as shown in fig. 33, a linkage rod 26 is connected between the trigger 21 and the cylinder locking member 6.

As shown in fig. 32, when the cylinder rod 311 is brought to the cylinder lock 6 by the transition gear 57, the cylinder lock 6 is inserted into the lock hole 3111 (see fig. 33), locking the cylinder rod 311;

as shown in fig. 35, when the trigger 21 is pulled, the trigger 21 drives the linkage rod 26 to move backward, the linkage rod 26 drives the cylinder locking piece 6 to lift upward, and then the cylinder locking piece 6 is released from the lock hole 3111, the cylinder rod 311 is unlocked, and the cylinder rod 311 extrudes gas under the action of the compression spring 312, and ejects the bullet 11 from the air nozzle 33.

Further, as shown in fig. 15-19, the linkage 4 is shaped like a dinosaur, and includes a mouth 41, a tail 42 and a foot 43;

when the linkage 4 is brought to the side of the clip 1, the bullet 11 is pushed into the mouth 41;

when the linkage 4 is pushed to be connected with the launching mechanism 3, the tail part 42 is butted with the launching mechanism 3;

the foot 43 is rotatably connected to the body 2 and can be rotated toward the cartridge holder 1 by the loading mechanism 5.

Further, the loading mechanism 5 comprises a push handle 51, the push handle 51 can slide back and forth along the gun body 2, the cartridge holder 1 is arranged at the front end of the gun body 2, and the firing mechanism 3 is arranged at the rear end of the gun body 2;

at the initial stage of pushing the push handle 51 backward, the cartridge clip 1 is driven to rotate one grid;

when the push handle 51 is pushed back to the bottom, the linkage piece 4 is driven to the side of the cartridge holder 1;

at the initial stage of pushing the handle 51 forward, the bullet 11 is pushed into the linkage 4;

when the handle 51 is pushed forward to the bottom, the link 4 is released, and the link 4 moves to connect with the launching mechanism 3.

Specifically, as shown in fig. 15 and 20, in the initial state, the link 4 is positioned on the rear side of the gun body 2, and the push handle 51 is positioned on the front side of the gun body 2.

In the initial stage of pushing the push handle 51 backwards, the cartridge clip 1 is driven to rotate one grid, so that one of the cartridge nests 13 is rotated to a position aligned with the ejection hole 22 of the gun body 2;

as shown in fig. 16 and 21, when the push handle 51 is pushed back to the bottom, the link 4 is rotated forward to the cartridge holder 1 side, and the mouth 41 of the link 4 is aligned with the ejection hole 22, and the cylinder rod 311 is chain-locked.

As shown in fig. 17 and 22, in the initial stage of pushing the push handle 51 forward, the bullet 11 is pushed into the mouth 41 of the linkage 4, and the dinosaur bites the bullet 11;

as shown in fig. 18 and 23, when the handle 51 is pushed forward to the bottom, the link 4 is released, and the link 4 rotates backward to connect with the launching mechanism 3, and the tail part 42 of the link 4 is butted with the air tap 33 of the launching mechanism 3.

As shown in fig. 19 and 25, the trigger 21 is actuated to generate an air flow in the air cylinder 31 and fire the bullet 11 in the mouth 41.

By implementing the present embodiment, it is achieved that the cartridge 11 is fired through the linkage 4, the linkage 4 being deformable before firing and the loading of the cartridge 11 being achieved. The linkage piece 4 is in a dinosaur shape, the head of the dinosaur is low, then the mouth bites the bullet, the head of the dinosaur is lifted, and finally the bullet is spit out from the mouth, so that the interest and the playability of the toy are improved.

The foregoing is considered as illustrative only of the principles and preferred embodiments of the invention. It should be noted that, for those skilled in the art, several other modifications can be made on the basis of the principle of the present invention, and the protection scope of the present invention should be regarded.

Claims (13)

1. A linkage multi-play launching device is characterized by comprising a launching body, a linkage piece and a launched object;

the linkage piece is arranged outside the launching body;

the shot object is detachably arranged on the linkage piece, and the linkage piece can drive the shot object to move from an assembling position to a shooting position on the shooting body;

when the launched object is in the launching position and the trigger of the launching body is pulled down, the launched object is launched out.

2. A linked multi-play launching device according to claim 1, wherein the linkage is slidable or swingable between the set-up position and the launch position on the launching body.

3. A linked multi-play launching device according to claim 1, wherein the launched object is mounted directly into the linkage; or, the emission body comprises a bullet hooking component, and the shot object is brought into the linkage piece by the bullet hooking component.

4. The linked multi-play launching device of claim 3, further comprising a magazine into which a plurality of the launchers are mounted, the magazine being removably mounted into the launching body;

the bullet hooking component is used for driving one shot object in the storage object to enter the linkage part.

5. A linked multi-play launching device according to claim 2, characterised in that the launching body includes an operating component for sliding or swinging the linkage.

6. The linked multi-play launching device of claim 5, wherein the launching body further comprises a catch assembly for bringing the launched object into the linkage, the operating assembly being linked with the catch assembly.

7. The linked multi-play launching device of claim 2, wherein a locking piece is provided in the launching body for locking the linked piece in the launching state, the locking piece is linked with the trigger, and an elastic piece is provided on the linked piece for accumulating energy in the 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 launched object is triggered to be launched through the movement of the linkage piece.

8. The linked multi-play launching device of claim 1, wherein a launcher for launching the launched object away from the linkage is provided in the launching body, the launcher being linked with the trigger;

when the trigger is pulled down, the launching piece drives the launched object to be launched.

9. A linked multi-play launching device according to claim 8, wherein a locking member is provided on the linkage member, and when the launched object leaves the linkage member, the launched object triggers the locking member to unlock and move the linkage member.

10. The linked multi-play launching device of claim 7, wherein a launcher for launching the launched object away from the linkage is provided in the launching body, the launcher being linked with the trigger;

when the trigger is pulled down, the linkage piece is triggered to move simultaneously, and the object to be shot is shot.

11. A linked multi-play launching device according to claim 1, wherein the linkage comprises a movable member, the linkage being configured in a first configuration when the movable member is in a first position, the linkage being configured in 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.

12. The linked multi-play launching device of claim 1, wherein the launching body further comprises a sliding platform to which the linkage is slidably connected, the linkage moving from one end of the sliding platform to the other end or from the sliding platform away from the launching body when the trigger is pulled down.

13. The linked multi-play launching device according to claim 1, wherein the launching body includes a driving component, a transmission component is provided on the linkage component, an input end of the transmission component is connected with the driving component, an output end of the transmission component is connected with the launched object mounted on the linkage component, and the driving component drives the launched object to store energy by power when being driven.

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