CN112393639B - Toy projectile gun - Google Patents

Abstract

The invention discloses a toy projectile gun, which comprises a cartridge clip and a gun body, wherein a plurality of bullets can be loaded in the cartridge clip, a trigger and a launching mechanism are arranged on the gun body, and the toy projectile gun also comprises a linkage piece which can move between a loading position close to the cartridge clip and a launching position close to the launching mechanism; the gun body is provided with a loading mechanism, and when the loading mechanism drives the linkage piece to move to a loading position, the linkage piece obtains a bullet from the cartridge clip; when the loading mechanism drives the linkage piece to move to the transmitting position, the linkage piece is in butt joint with the transmitting mechanism; the trigger is linked with the firing mechanism, and when the trigger is pulled, the trigger triggers the firing mechanism to fire the bullets in the linkage. According to the toy gun, the loading mechanism, the linkage piece, the cartridge clip and the gun body are matched, so that the linkage bullet shooting is realized, and the playability and the interestingness of the toy gun are improved.

Description

Toy projectile gun

Technical Field

The invention relates to the technical field of soft bullet gun emitters, in particular to a toy projectile gun.

Background

The existing mainstream soft bullet launcher directly shoots out soft bullets by compressing an air cylinder. The soft bullet gun launcher has single shape, simple operation and lack of challenges and fun.

Therefore, there is a need for a toy projectile gun that can achieve coordinated firing of soft bullets.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides a toy projectile gun capable of realizing linkage firing of soft bullets.

The technical proposal of the invention provides a toy projectile gun, which comprises a cartridge clip and a gun body, wherein a plurality of bullets can be put in the cartridge clip, a trigger and a firing mechanism are arranged on the gun body,

the toy projectile gun further includes a linkage movable between a loading position proximate the clip and a firing position proximate the firing mechanism;

the gun body is provided with a loading mechanism, and when the loading mechanism drives the linkage piece to move to the loading position, the linkage piece obtains a bullet from the cartridge clip;

when the loading mechanism drives the linkage piece to move to the transmitting position, the linkage piece is in butt joint with the transmitting mechanism;

the trigger is linked with the firing mechanism, and when the trigger is pulled, the trigger triggers the firing mechanism to fire the bullet in the linkage.

Further, the loading mechanism comprises a bullet hooking assembly, the bullet hooking assembly is located at the cartridge clip, and when the loading mechanism drives the linkage piece to move to the loading position, the bullet hooking assembly pushes one bullet in the cartridge clip into the linkage piece.

Further, the loading mechanism further comprises a push handle, and when the push handle slides towards the emission position, the hooking component moves from the gun body to one of the bullet nests of the cartridge clip;

when the pushing handle slides towards the loading position, the bullet hooking component is driven to hook the bullet in the bullet nest into the linkage piece.

Further, the hooking and elastic assembly comprises a pull rope, a telescopic hook and an elastic piece, one end of the pull rope is connected with the push handle, the other end of the pull rope is connected with one end of the telescopic hook, and the telescopic hook is connected with the elastic piece;

when the pushing handle slides towards the loading position, the pull rope is driven, the telescopic hook is pulled by the pull rope, the bullet in the bullet nest is hooked into the linkage part by the telescopic hook, and the elastic part stores energy;

when the pushing handle slides towards the launching position, the elastic piece is released, and the elastic piece drives the telescopic hook to be inserted into one of the spring nests of the clip.

Further, the cartridge clip is rotatably connected to the gun body, and the loading mechanism is linked with the cartridge clip to control the cartridge clip to rotate.

Further, the loading mechanism comprises a cartridge clip poking assembly, when the loading mechanism drives the linkage piece to move to the loading position, the loading mechanism drives the cartridge clip poking assembly, and the cartridge clip poking assembly drives the cartridge clip to rotate for one grid, and each grid corresponds to one bullet.

Further, the cartridge clip poking assembly comprises a poking block and a ratchet wheel, the poking block is linked with the pushing handle, the pushing handle drives the poking block to move once, the poking block pokes the ratchet wheel to rotate once, and the ratchet wheel rotates once the cartridge clip rotates one lattice.

Further, the clip is detachably mounted on the gun body, a clip groove is formed in the front end of the gun body, a clip button and a tripping button are arranged in the clip groove, after the clip is inserted into the clip groove, the clip button locks the clip, and the tripping button is used for unlocking the clip.

Further, the launching mechanism is a pneumatic launching mechanism or an elastic launching mechanism.

Further, the pneumatic emission mechanism comprises an air cylinder, an air pipe and an air tap, wherein the air cylinder is communicated with the air tap through the air pipe;

when the linkage piece is communicated with the air tap, the trigger is triggered, and the air cylinder sprays air into the linkage piece and is used for shooting out the bullets in the linkage piece.

Further, the feeding mechanism further comprises a first rack, a transition gear and a second rack, the inflator comprises an inflator rod and a pressure spring, the pushing handle can slide back and forth along the gun body, the pushing handle is fixedly connected with the first rack, and the second rack is fixedly connected with the inflator rod;

when the pushing handle is pushed towards one side, the first rack is driven to move, the first rack unidirectionally drives the transition gear to rotate, the transition gear drives the second rack to move, and the second rack drives the inflator rod to overcome the force of the pressure spring and be locked;

when the trigger is triggered, the inflator rod is released, and under the action of the pressure spring, the inflator rod extrudes gas and is sprayed out from the air tap.

Further, the elastic firing mechanism comprises an elastic push rod, and when the trigger is triggered, the elastic push rod stretches into the linkage piece, so that the bullet in the linkage piece is ejected.

After the technical scheme is adopted, the method has the following beneficial effects:

the toy ejection gun is provided with the linkage piece which can be associated with the operation of the toy ejection gun to generate various visual action changes, so that the problems of single playing and no ornamental value of the toy ejection gun are solved, and the cool feeling of the toy ejection gun is increased. And moreover, the bullet is taken out from the cartridge clip and loaded through the action change of the linkage piece, the loading mode is extremely original and interesting, and all actions are closely matched and correlated, so that the design is ingenious. According to the invention, through the coordination of the loading mechanism, the linkage piece, the cartridge clip and the gun body, the linkage bullet shooting is realized, and the playability and the interestingness of the toy gun are increased.

Drawings

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

FIG. 1 is a schematic illustration of an initial state of a toy projectile gun in accordance with one embodiment of the invention;

FIG. 2 is a schematic illustration of a toy projectile gun of one embodiment of the invention with the push handle pushed rearward;

FIG. 3 is a schematic illustration of an initial stage of the push handle of the toy projectile gun being pushed forward in one embodiment of the invention;

FIG. 4 is a schematic illustration of the push handle of a toy projectile gun pushed forward to the bottom in one embodiment of the invention;

FIG. 5 is a schematic illustration of a toy projectile gun trigger in one embodiment of the invention;

FIG. 6 is a schematic internal view of a toy projectile gun according to an embodiment of the invention in its initial configuration;

FIG. 7 is a schematic view of the internal structure of a toy projectile gun according to one embodiment of the invention with the push handle pushed rearward;

FIG. 8 is a schematic view of the internal structure of the toy projectile gun of one embodiment of the invention at an initial stage of forward pushing of the push handle;

FIG. 9 is a schematic view of the internal structure of a toy projectile gun with the push handle pushed forward to the bottom in one embodiment of the invention;

FIG. 10 is a schematic view of the internal structure of a toy projectile gun trigger in accordance with one embodiment of the invention;

FIG. 11 is an exploded view of the clip, bullet and body;

FIG. 12 is an exploded view of the cartridge clip and bullet;

FIG. 13 is a perspective view of the linkage;

FIG. 14 is a perspective view of the gun body;

FIG. 15 is a schematic view of a side of the clip toggle assembly;

FIG. 16 is a schematic view of another side of the clip toggle assembly;

FIG. 17 is a schematic view of the slider engaging the foot;

FIG. 18 is a schematic view of the engagement of the loading mechanism, cartridge and cartridge lock;

FIG. 19 is a schematic view of the trigger, cartridge lock engaged with the cartridge rod;

FIG. 20 is a schematic view of the engagement of the cartridge lock with the cartridge stem;

FIG. 21 is an internal schematic view of the linkage;

FIG. 22 is a schematic view of a slider and clip toggle assembly;

FIG. 23 is a schematic view of the foot engaging the linkage locking assembly;

FIG. 24 is a schematic view of the hooking and snapping assembly, foot and linkage locking assembly;

fig. 25 is a schematic view of a hooking member.

Reference numeral control table:

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

gun body 2: trigger 21, clip groove 22, clip button 23, trip button 24, bullet hole 25 and linkage rod 26;

emission mechanism 3: inflator 31, gas pipe 32, gas nipple 33, inflator rod 311, compression spring 312, lock hole 3111;

linkage 4: mouth 41, tail 42, foot 43, rotation shaft 44, spring tube 45, connecting air tube 46, plug 451;

the feeding mechanism 5: push handle 51, clip toggle assembly 52, slider 53, linkage locking assembly 54, hook spring assembly 55, first rack 56, transition gear 57, second rack 58, dial 521, ratchet 522, pin 523, chute 531, ramp 532, lock slot 541, draw cord 551, telescoping hook 552, unlocking portion 553, insertion rod 5521, tension spring 5522, hook portion 5523;

a cartridge lock 6.

Detailed Description

Specific embodiments of the present invention will be further described below with reference to the accompanying drawings.

It is to be readily understood that, according to the technical solutions of the present invention, those skilled in the art may replace various structural modes and implementation modes with each other without changing the true spirit of the present invention. Accordingly, the following detailed description and drawings are merely illustrative of the invention and are not intended to be exhaustive or to limit the invention to the precise form disclosed.

Terms of orientation such as up, down, left, right, front, rear, front, back, top, bottom, etc. mentioned or possible to be mentioned in the present specification are defined with respect to the configurations shown in the drawings, which are relative concepts, and thus may be changed according to different positions and different use states thereof. These and other directional terms should not be construed as limiting terms.

In one embodiment of the present invention, as shown in fig. 1, a toy projectile gun comprises a cartridge clip 1 and a gun body 2, wherein a plurality of bullets 11 (see fig. 11) can be loaded in the cartridge clip 1, and a trigger 21 and a firing mechanism 3 (see fig. 6) are arranged on the gun body 2;

the toy projectile gun also includes a linkage 4,

the linkage 4 is movable between a loading position close to the magazine 1 and a firing position close to the firing mechanism 3;

the gun body 2 is provided with a loading mechanism 5, and when the loading mechanism 5 drives the linkage piece 4 to move to a loading position, the linkage piece 4 obtains a bullet 11 from a cartridge clip;

when the loading mechanism 5 drives the linkage piece 4 to move to the transmitting position, the linkage piece 4 is in butt joint with the transmitting mechanism 33;

the trigger 21 is interlocked with the firing mechanism 3, and when the trigger 21 is actuated, the trigger 21 triggers the firing mechanism 3 to fire the bullet 11 in the linkage 4.

In the embodiment, the linkage piece 4 which can be associated with the operation of the toy ejection gun to generate various visual action changes is arranged on the toy ejection gun, so that the problems of single playing and no ornamental value of the toy ejection gun are solved, and the cool feeling of the toy ejection gun is increased. Moreover, the bullet 11 is taken out from the cartridge clip 1 and loaded through the action change of the linkage piece 4, the loading mode is extremely original and interesting, and the actions are closely matched and correlated, so that the design is ingenious.

Specifically, in this embodiment, the linkage member 4 is dinosaur-shaped, the clip 1 is disposed at the front end (i.e. the left side in fig. 1) of the gun body 2, the launching mechanism 3 is disposed at the rear end (i.e. the right side in fig. 1) of the gun body 2, and the loading mechanism 5 is mounted on the gun body 2 and can slide back and forth along the gun body 2. In this embodiment, the front end of the gun body 2 is a loading position, and the rear end is a firing position.

In the initial state of the toy projectile gun, the linkage 4 is located at the rear end of the gun body 2 and is connected with the launching mechanism 3 installed inside the gun body 2.

The clip 1 is detachably connected to the gun body 2, and the clip 1 is already installed in the gun body 2 in fig. 1.

As shown in fig. 2, the linkage 4 is moved in the direction of the clip 1 (loading position) by the loading mechanism 5, so that the linkage 4 receives a bullet 11 in the clip 1.

As shown in fig. 3, the loading mechanism 5 pushes a cartridge 11 in the cartridge holder 1 into the linkage 4.

As shown in fig. 4, the loading mechanism 5 releases the linkage 4 so that the linkage 4 returns to the position (firing position) where it is connected to the firing mechanism 3.

As shown in fig. 5, trigger 21 is pulled and firing mechanism 3 fires a bullet 11 in linkage 4.

In this embodiment, the linkage 4 is driven by the loading mechanism 5 and a bullet 11 is pushed into the linkage 4, so that the firing mechanism 3 fires the bullet 11 through the linkage 4, thereby increasing the playability and interest of the toy gun. And the linkage piece 4 is animal-shaped, 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 of other animal, or automotive, or aircraft configurations.

Further, as shown in fig. 11, the clip 1 is detachably mounted on the gun body 2, a clip groove 22 is provided at the front end of the gun body 2, a clip button 23 and a release button 24 are provided in the clip groove 22, and after the clip 1 is inserted into the clip groove 22, the clip button 23 locks the clip 1, and the release button 24 is used for unlocking the clip 1.

Specifically, the clip 23 is controlled by the release button 24, and when the release button 24 is pressed, the clip 23 is retracted, 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 is extended to lock the clip 1 in the clip groove 22 of the gun body 2.

Further, as shown in fig. 11, a hexagonal cylindrical through hole 12 is provided in the clip 1, the trip button 24 is a hexagonal cylinder, and the trip button 234 is inserted into the cylindrical through hole 12 of the clip 1, for driving the clip 1 to rotate.

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

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

As shown in fig. 12, the clip 1 is cylindrical and includes a plurality of nests 13, and each of the nests 13 can receive one of the bullets 11.

The bullet 11 in this embodiment is a soft bullet made of foam and is placed in the bullet nest 13.

The bullet 11 is provided with a bullet through hole 111, and the bullet through hole 111 is used for being in interference fit with a plug 451 (see fig. 13) in the linkage 4, and mainly increases the friction force between the bullet 11 and the plug 451, so that the gas needs to reach the moment that the friction force can be overcome, and the bullet 11 can be ejected more forcefully. Avoiding that the bullet 11 is easily impacted by weaker gas, resulting in a short shot of bullet 11.

As shown in fig. 13, the link 4 is provided with a barrel 45, the barrel 45 is positioned inside the mouth 41, and the barrel 45 is provided with a plug 451. When the bullet 11 is pushed into the barrel 45, the plug 451 is inserted into the bullet through hole 111 and is interference fit so that the bullet 11 can be held in the link 4.

Further, the clip 1 is rotatably connected to the gun body 2, and the loading mechanism 5 is linked with the clip 1 to control the rotation of the clip 1. The loading mechanism 5 comprises a cartridge clip poking assembly 52, and when the loading mechanism 5 drives the linkage 4 to move to the loading position, the loading mechanism 5 drives the cartridge clip poking assembly 52, and the cartridge clip poking assembly 52 drives the cartridge clip 1 to rotate one cell, and each cell of the cartridge clip 1 is aligned with a cartridge hole 25 corresponding to one cartridge 11.

In this embodiment, as shown in fig. 6 and 15, the loading mechanism 5 includes a push handle 51 and a clip poking assembly 52, the push handle 51 can slide along the gun body 2, when the push handle 51 slides towards one side, the clip poking assembly 52 is driven, the clip poking assembly 52 drives the clips 1 to rotate one compartment through the trip button 24, and each compartment of the clips 1 is aligned with a bullet 11 corresponding to a bullet hole 25.

Specifically, as shown in fig. 22, the loading mechanism 5 further includes a sliding member 53, and 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. 15, the sliding member 53 is provided with a sliding groove 531, and in an initial state, the sliding groove 531 can drive the clip poking assembly 52 to move.

Specifically, as shown in fig. 15, the clip poking assembly 52 includes a poking block 521, a ratchet 522 and a pin 523, the pin 523 is inserted into the sliding groove 531 in the initial state of fig. 1, when the push handle 51 drives the sliding piece 53 to move backward, the sliding groove 531 of the sliding piece 53 drives the pin 523 backward, the pin 523 drives the poking block 521 to move backward, the poking block 521 pokes the ratchet 522, the ratchet 522 is mounted at the rear end of the trip button 24, the push handle 51 drives the poking block 521 to move once, the poking block 521 pokes the ratchet 522 to rotate one tooth, the ratchet 522 drives the trip button 24 to rotate, and the trip button 24 drives the clip 1 to rotate one lattice.

The clip 1 is rotated by the push handle 51 to rotate the bullet 11 in one of the nests 13 to a position ready for entry into the linkage 4.

As shown in fig. 14, the gun body 2 is provided with a bullet outlet 25, and one bullet nest 13 is aligned with the bullet outlet 25 when the clip 1 rotates one frame.

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

Further, as shown in fig. 17, the linkage member 4 is rotatably connected with the gun body 2, the loading mechanism 5 includes a push handle 51 and a sliding member 53, the push handle 51 slides along the gun body 2, the push handle 51 is fixedly connected with the sliding member 53, and when the push 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 towards one side of the cartridge clip 1.

Specifically, the sliding member 53 is provided with a slope 532, when the push handle 51 moves backward, 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 rotation shaft 44 (see fig. 13), and the slope 532 pushes the lower part of the foot 43, so that the whole dinosaur-shaped linkage member 4 rotates forward toward the cartridge clip 1.

Optionally, a torsion spring is mounted at the rotation axis 44, which stores energy when the linkage 4 rotates in the direction of the cartridge clip 1. When the push handle 51 slides forward, the inclined surface 532 is separated from the foot 43 to release the link 4, and the link 4 returns to the initial position of fig. 1 by the torsion spring, i.e., rotates backward to be connected with the launching mechanism 3.

Alternatively, a torsion spring may not be provided, and a slope may be added to the slider 53, and the slope toggles the linkage 4 to flip backward when the slider 53 slides forward.

Further, the loading mechanism 5 includes a hook assembly 55, the hook assembly 55 is located at the clip 1, and when the loading mechanism 5 drives the linkage 4 to move to the loading position, the hook assembly 55 pushes a bullet 11 in the clip 1 into the linkage 4.

In this embodiment, as shown in fig. 7-8, the loading mechanism 5 includes a push handle 51 and a hook spring assembly 55, and when the push handle 51 slides toward one side, the hook spring assembly 55 moves from the gun body 2 into one of the spring nests 13 of the clip 1;

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

Specifically, as shown in fig. 25, the hooking and elastic component 55 includes a pull cord 551, a telescopic hook 552 and an elastic member, in this embodiment, the elastic member is a tension spring 5522, and the pull cord 551 is connected with the push handle 51. The telescopic hook 552 further comprises an insertion rod 5521 and a hook portion 5523, wherein the pulling rope 551 is connected with one end of the insertion rod 5521, the hook portion 5523 is rotatably connected with the other end of the insertion rod 5521, one end of the tension spring 5522 is connected with the middle section of the insertion rod 5521, and the other end of the tension spring 5522 is connected with the gun body 2.

As shown in fig. 7, when the push handle 51 slides backward, the pulling cord 551 is released, and the tension spring 5522 drives the insertion rod 5521 to extend into the clip groove 22, and the hook portion 5523 is folded and retracted into the insertion rod 5521 while the insertion rod 5521 passes through the clip groove 22. After the front end of the insertion rod 5521 passes through the clip groove 22, the hook 5523 is rotated to be spread and extended into one of the ammunition nests 13 to be contacted with the front end of the ammunition 11.

As shown in fig. 8, when the push plate 51 slides forward, the pull rope 551 is driven, the pull rope 551 pulls the insertion rod 5521 backward, and the hook 5523 drives a bullet 11 into the linkage 4, that is, the mouth 41 of the dinosaur, so that the tension spring 5522 stores energy.

Further, as shown in fig. 23 to 24, the loading mechanism 5 further includes a linkage member locking assembly 54, and after the linkage member 4 is turned toward the clip 1, the linkage member locking assembly 54 locks the linkage member 4;

when the push handle 51 slides to the other side, the link locking assembly 54 is unlocked, and the release link 4 is turned toward one side of the launching mechanism 3.

Specifically, as shown in fig. 23, the link locking assembly 54 further includes a locking groove 541, and when the inclined surface 532 pushes the foot 43 of the link 4 rearward, the foot 43 is caught in the locking groove 541, and locked in this position, so that the link 4 is maintained in a state of being turned forward.

As shown in fig. 24, when the hooking member 55 is retracted rearward to hook the bullet 11 into the link 4, the unlocking portion 553 on the hooking member 55 hits the link locking member 54, so that the link locking member 54 is disengaged from the leg 43. The foot 43 drives the entire linkage 4 to turn back at the position of the return spring, so that the linkage 4 is connected with the launching mechanism 3.

Further, as shown in fig. 6, the emission mechanism 3 is a pneumatic emission mechanism, and the pneumatic emission mechanism comprises an air cylinder 31, an air pipe 32 and an air tap 33, wherein the air cylinder 31 is communicated with the air tap 33 through the air pipe 32;

when the linkage 4 is communicated with the air tap 33, the trigger 21 is pulled, and the air cylinder 31 sprays air into the linkage 4, so as to launch the bullet 11 in the linkage 4.

Specifically, as shown in fig. 21, the linkage 4 is provided with a connecting air pipe 46 and a spring tube 45, the connecting air pipe 46 communicates with the spring tube 45, and an opening of the connecting air pipe 46 is opened from the tail portion 42.

When the linkage 4 is in butt joint with the air tap 33 of the launching mechanism 3, the air of the air cylinder 31 sequentially passes through the air pipe 32, the air tap 33, the connecting air pipe 46 and the bullet cylinder 45 to launch the bullet 11.

Further, as shown in fig. 18, the loading mechanism 5 further includes a push handle 51, a first rack 56, a transition gear 57 and a second rack 58, the inflator 31 includes an inflator 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 inflator rod 311;

when the push handle 51 is pushed towards one side, the first rack 56 is driven to move, the first rack 56 unidirectionally drives the transition gear 57 to rotate, the transition gear 57 drives the second rack 58 to move, and the second rack 58 drives the inflator rod 311 to overcome the compression spring 312 to be linked and locked;

when the trigger 21 is actuated, the air cylinder rod 311 is released, and the air cylinder rod 311 presses the air to be ejected from the air tap 33 by the pressure spring 312.

Specifically, the first rack 56 is fixedly connected to the push handle 51, and the longitudinal direction thereof is arranged in 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 being in engagement with one of the gears and a second rack 58 being in engagement with the other gear. The first rack 56 can only realize unidirectional driving of the transition gear 57, i.e. when moving towards one direction, the second rack 58 can be driven by the transition gear 57, and when moving towards the other direction, the second rack 58 cannot be driven. The second rack 58 is integral with a cylinder rod 311, and the cylinder rod 311 is inserted into the cylinder 31.

As shown in fig. 7, when the push handle 51 slides backwards, the first rack 56 is driven to move, the first rack 56 unidirectionally drives the transition gear 57 to rotate, the transition gear 57 drives the second rack 58 to move, and the second rack 58 drives the inflator rod 311 to overcome the compression spring 312 to be winded and locked;

when the push handle 51 slides forward, the second rack 58 is not driven to move, and the position of the inflator stem 311 is kept unchanged.

As shown in fig. 10, when the trigger 21 is pulled, the trigger 21 releases the gas cylinder 311, and the gas cylinder 311 presses the gas to be ejected from the gas nipple 33 by the pressure spring 312.

Further, as shown in fig. 18-19, the toy projectile gun further comprises an air cylinder locking piece 6, wherein the air cylinder locking piece 6 is linked with the trigger 21, and a lock hole 3111 is formed on the air cylinder rod 311;

when the air cylinder rod 311 is driven to the air cylinder locking piece 6 by the transition gear 57, the air cylinder locking piece 6 is inserted into the lock hole 3111 to lock the air cylinder rod 311;

when the trigger 21 is actuated, the trigger 21 causes the cartridge lock 6 to release the cartridge rod 311.

Specifically, as shown in fig. 19, a link lever 26 is connected between the trigger 21 and the cartridge lock 6.

As shown in fig. 18, when the cartridge lever 311 is brought to the cartridge lock 6 by the transition gear 57, the cartridge lock 6 is inserted into the lock hole 3111 (see fig. 19), locking the cartridge lever 311;

as shown in fig. 20, when the trigger 21 is pulled, the trigger 21 drives the link lever 26 to move backward, the link lever 26 drives the air cylinder locking member 6 to lift upward, the air cylinder locking member is released from the lock hole 3111, the air cylinder lever 311 is unlocked, and the air cylinder lever 311 presses the air under the action of the pressure spring 312, and the air is ejected from the air nozzle 33 to eject the bullet 11.

Alternatively, the firing mechanism 3 may be an elastic firing mechanism that includes an elastic push rod that extends into the linkage 4 when the trigger 21 is actuated, thereby pushing the bullet 11 out of the linkage 4.

Further, as shown in fig. 1-5, the linkage 4 is dinosaur shaped, and the linkage 4 includes a mouth 41, a tail 42, and a foot 43;

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

when the linkage piece 4 is pushed to be connected with the launching mechanism 3, the tail part 42 is in butt joint with the launching mechanism 3;

the leg 43 is rotatably connected to the gun body 2 and can be rotated toward the clip 1 by the loading mechanism 5.

Further, the loading mechanism 5 comprises a push handle 51, the push handle 51 can slide forwards and backwards along the gun body 2, the cartridge clip 1 is arranged at the front end of the gun body 2, and the launching mechanism 3 is arranged at the rear end of the gun body 2;

the initial stage of pushing the push handle 51 backwards drives the clip 1 to rotate for one frame;

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

an initial stage of pushing the push handle 51 forward, pushing the bullet 11 into the link 4;

when the push handle 51 is pushed forward to the bottom, the link 4 is released, and the link 4 is moved to be connected with the launching mechanism 3, that is, the launching position.

Specifically, as shown in fig. 1 and 6, in the initial state, the link 4 is positioned at the rear side of the gun body 2, and the push handle 51 is positioned at the front side of the gun body 2.

At the initial stage of pushing the push handle 51 backwards, the clip 1 is driven to rotate for one frame, so that one of the spring nests 13 is rotated to a position aligned with the spring outlet 22 of the gun body 2;

as shown in fig. 2 and 7, when the push knob 51 is pushed rearward to the bottom, the link 4 is rotated forward to the clip 1 side, and at this time, the mouth 41 of the link 4 is aligned with the ejection hole 22, and the air cylinder lever 311 is locked by the upper chain.

As shown in fig. 3 and 8, 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. 4 and 9, when the push handle 51 is pushed forward to the bottom, the linkage 4 is released, so that the linkage 4 rotates backward to be connected with the launching mechanism 3, and at this time, the tail 42 of the linkage 4 is in butt joint with the air tap 33 of the launching mechanism 3.

As shown in fig. 5 and 10, the trigger 21 is pulled to cause the air cylinder 31 to generate an air flow to fire the cartridge 11 of the mouth 41.

By implementing the present embodiment, it is achieved that the bullet 11 is launched by the linkage 4, the linkage 4 being deformable before launch and the loading of the bullet 11 being achieved. The linkage piece 4 is dinosaur molding, presents dinosaur head low, then the bullet is bitten to the mouth, and dinosaur's head lifts up, and finally from the play mode that the bullet was spouted to the mouth, has increased the interest and the playability of toy.

What has been described above is merely illustrative of the principles and preferred embodiments of the present invention. It should be noted that several other variants are possible to those skilled in the art on the basis of the principle of the invention and should also be considered as the scope of protection of the present invention.

Claims (9)

1. A toy projectile gun comprises a cartridge clip and a gun body, wherein a plurality of bullets can be loaded in the cartridge clip, a trigger and a firing mechanism are arranged on the gun body,

the toy projectile gun further includes a linkage movable between a loading position proximate the clip and a firing position proximate the firing mechanism;

the gun body is provided with a loading mechanism, and when the loading mechanism drives the linkage piece to move to the loading position, the linkage piece obtains a bullet from the cartridge clip;

when the loading mechanism drives the linkage piece to move to the transmitting position, the linkage piece is in butt joint with the transmitting mechanism;

the trigger is linked with the launching mechanism, and when the trigger is pulled, the trigger triggers the launching mechanism to launch the bullet in the linkage; the loading mechanism comprises a bullet hooking assembly, the bullet hooking assembly is positioned at the cartridge clip, and when the loading mechanism drives the linkage piece to move to the loading position, the bullet hooking assembly pushes one bullet in the cartridge clip into the linkage piece;

the loading mechanism further comprises a push handle, and when the push handle slides towards the transmitting position, the hook elastic component moves from the gun body to one of the elastic nests of the elastic clip;

when the pushing handle slides towards the loading position, the bullet hooking component is driven to hook the bullet in the bullet nest into the linkage piece; the hook elastic component comprises a pull rope, a telescopic hook and an elastic piece, one end of the pull rope is connected with the push handle, the other end of the pull rope is connected with one end of the telescopic hook, and the telescopic hook is connected with the elastic piece;

when the pushing handle slides towards the loading position, the pull rope is driven, the telescopic hook is pulled by the pull rope, the bullet in the bullet nest is hooked into the linkage part by the telescopic hook, and the elastic part stores energy;

when the pushing handle slides towards the launching position, the elastic piece is released, and the elastic piece drives the telescopic hook to be inserted into one of the spring nests of the clip.

2. The toy projectile gun of claim 1, wherein the clip is rotatably connected to the gun body, the loading mechanism being in linkage with the clip to control rotation of the clip.

3. The toy projectile gun of claim 2, wherein the loading mechanism includes a clip toggle assembly, the loading mechanism driving the clip toggle assembly when the loading mechanism drives the linkage to move to the loading position, the clip toggle assembly driving the clips to rotate one compartment, one for each of the cartridges.

4. A toy projectile gun as claimed in claim 3, wherein,

the cartridge clip poking assembly comprises a poking block and a ratchet wheel, wherein the poking block is in linkage with the pushing handle, the pushing handle drives the poking block to move once, the poking block pokes the ratchet wheel to rotate once, and the ratchet wheel rotates once to drive the cartridge clip to rotate one frame.

5. The toy projectile gun of claim 1, wherein the clip is detachably mounted on the gun body, a clip groove is formed in the front end of the gun body, a clip button and a release button are arranged in the clip groove, and the clip button locks the clip after the clip is inserted into the clip groove, and the release button is used for unlocking the clip.

6. The toy projectile gun of claim 1, wherein the firing mechanism is a pneumatic firing mechanism or an elastic firing mechanism.

7. The toy projectile gun of claim 6, wherein the pneumatic firing mechanism comprises an air cylinder, an air tube, and an air tap, the air cylinder in communication with the air tap through the air tube;

when the linkage piece is communicated with the air tap, the trigger is triggered, and the air cylinder sprays air into the linkage piece and is used for shooting out the bullets in the linkage piece.

8. The toy projectile gun of claim 7, wherein the loading mechanism further comprises a first rack, a transition gear, and a second rack, the gas cylinder comprises a gas cylinder rod and a pressure spring, the push handle can slide back and forth along the gun body, the push handle is fixedly connected with the first rack, and the second rack is fixedly connected with the gas cylinder rod;

when the pushing handle is pushed towards one side, the first rack is driven to move, the first rack unidirectionally drives the transition gear to rotate, the transition gear drives the second rack to move, and the second rack drives the inflator rod to overcome the force of the pressure spring and be locked;

when the trigger is triggered, the inflator rod is released, and under the action of the pressure spring, the inflator rod extrudes gas and is sprayed out from the air tap.

9. The toy projectile gun of claim 6, wherein the resilient firing mechanism includes a resilient push rod that extends into the linkage to expel the bullet from the linkage when the trigger is actuated.

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