CN111780618A - Toy emitter - Google Patents

Abstract

The invention discloses a toy launcher which comprises a launcher shell and a storage box detachably connected with the launcher shell, wherein the storage box is used for containing at least two toy pieces, the toy launcher also comprises a loading mechanism, a driving mechanism and a launching mechanism which are arranged in the launcher shell, the loading mechanism is used for driving the toy pieces in the storage box to the driving mechanism, the driving mechanism can accelerate the toy pieces, and the launching mechanism can launch the accelerated toy pieces. The invention drives the toy piece to the driving mechanism through the loading mechanism, accelerates the toy piece by using the driving mechanism, and finally launches the toy piece through the launching mechanism. Through loading, accelerating and launching a plurality of toy pieces one by one, continuous acceleration and continuous launching are realized, the launching efficiency is improved, a plurality of people can compete and play at the same time, and the interest and the challenge of the toy are increased.

Description

Toy emitter

Technical Field

The invention relates to the technical field of toys, in particular to a toy launcher.

Background

The existing mainstream launching trolley is basically not provided with a power mechanism or a continuous accelerating device, and is mainly launched by hand pushing or hand dialing acceleration, so that high-speed power and effect cannot be generated by continuous acceleration, and only a single trolley can be launched during each launching.

Therefore, there is a need for a toy launcher that can continuously accelerate and launch multiple toy pieces in succession.

Disclosure of Invention

The present invention is directed to overcoming the deficiencies of the prior art and providing a toy launcher that is capable of continuously accelerating and launching a plurality of toy pieces.

The technical scheme of the invention provides a toy launcher which comprises a launcher shell and a storage box detachably connected with the launcher shell, wherein the storage box is used for containing at least two toy pieces, the toy launcher also comprises a loading mechanism, a driving mechanism and a launching mechanism, the loading mechanism is installed in the launcher shell and used for driving the toy pieces in the storage box to the driving mechanism, the driving mechanism can accelerate the toy pieces, and the launching mechanism can launch the accelerated toy pieces.

Furthermore, an accelerating emission area is arranged in the emitter shell, a plug-in port for the storage box to be plugged in is arranged at the position of the accelerating emission area, and when the storage box is inserted into the plug-in port, the first toy piece in the storage box automatically enters the accelerating emission area.

Furthermore, a propelling mechanism is arranged in the storage box and used for propelling the toy piece in the storage box to the opening direction of the storage box;

the opening part is provided with a locking piece for limiting the toy piece at the opening position, when the storage box is arranged in the insertion port, the locking piece is unlocked, and the pushing mechanism pushes the first toy piece in the storage box into the accelerating launching area.

Further, the toy launcher may further comprise a blocking mechanism that separates a first of the toy pieces from other toy pieces remaining in the pocket as the loading mechanism is pulled.

Furthermore, a pushing mechanism is arranged in the launcher shell and used for driving the storage box connected to the inserting port to move, when the storage box is inserted into the inserting port, the first toy piece automatically enters the accelerated launching area, and then the toy pieces placed at other positions in the storage box are driven to the position of the accelerated launching area through the operation of the pushing mechanism.

Furthermore, the propelling mechanism is a screwing mechanism, the screwing mechanism is used for driving the storage box connected into the inserting port to rotate, and the toy pieces placed at other positions in the storage box are rotated to the position of the accelerated emission area through the operation of the screwing mechanism.

Further, the loading mechanism comprises a push inclined plane pin, a sliding groove is correspondingly formed in the screwing mechanism, and when the loading mechanism is pulled, the push inclined plane pin is driven to move in the sliding groove, so that the screwing mechanism drives the storage box to rotate.

Furthermore, a clamping position is arranged on the storage box, and a buckle and a dismounting key are arranged on the emitter shell;

when the storage box is connected with the interface, the buckle is clamped with the clamping position;

the button is detached through pressing, so that the buckle is separated from the clamping position, and the storage box is detached.

Furthermore, the loading mechanism comprises a pull handle and a top piece, wherein the pull handle partially extends out of the launcher shell, and when the pull handle is pulled to move to the position of the driving mechanism, the pull handle drives the top piece to push the toy piece, so that the toy piece is connected to the driving mechanism.

Further, the driving mechanism has two driving forces, one is that the driving mechanism is compressed backwards when the toy piece is mounted, so that the driving mechanism has a forward ejection driving force; the other is a rotational driving force provided to the toy piece by a power member after the toy piece is mounted.

Further, the power part is an independently accelerated pull rope assembly, or the loading mechanism is used as the power part of the driving mechanism.

Further, when the loading mechanism is used as a power piece of the driving mechanism,

the driving mechanism comprises an ejection driving assembly and a rotation driving assembly which are independently arranged, the ejection driving assembly is driven by the loading mechanism to store energy and then can be locked in an energy storage state, the loading mechanism provides rotating force for the rotation driving assembly, and the ejection driving assembly is unlocked under the buckling of the launching mechanism, so that the toy piece is ejected.

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

the launcher shell is matched with the storage box provided with a plurality of toy pieces, the toy pieces are driven to the driving mechanism through the loading mechanism, the toy pieces are accelerated by the driving mechanism, and finally the toy pieces are launched out through the launching mechanism. Through loading, accelerating and launching a plurality of toy pieces one by one, continuous acceleration and continuous launching are realized, the launching efficiency is improved, a plurality of people can compete and play at the same time, and the interest and the challenge of the toy are increased.

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 view of a side loading clip coupling gun loaded into a magazine according to one embodiment of the present invention;

FIG. 2 is a state diagram of the loading acceleration of a side-loading clip continuous shooting gun in accordance with an embodiment of the present invention;

FIG. 3 is a state view of a side-loading clip coupling gun launching toy piece in accordance with one embodiment of the present invention;

FIG. 4 is a schematic view of a gun body and a magazine according to an embodiment of the present invention;

FIG. 5 is a schematic view of an internal structure of a storage box according to an embodiment of the present invention;

FIG. 6 is a schematic view of a partial structure of a gun body according to an embodiment of the present invention;

FIG. 7 is a schematic view of the internal structure of the gun body and the magazine when they are installed in accordance with one embodiment of the present invention;

FIG. 8 is a schematic view of a blocking mechanism in accordance with one embodiment of the present invention;

FIG. 9 is a schematic view of a side dam of an embodiment of the present invention before it is locked with a side dam button;

FIG. 10 is a schematic view of the side dam and side dam buckle locking according to one embodiment of the present invention;

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

FIG. 12 is a schematic view of an acceleration mechanism according to an embodiment of the present invention;

FIG. 13 is a schematic view of a loading mechanism according to one embodiment of the present invention;

FIG. 14 is a schematic view of a loading mechanism of the first embodiment of the present invention prior to loading;

FIG. 15 is a schematic view of the loading mechanism after loading in accordance with one embodiment of the present invention;

FIG. 16 is a schematic illustration of a side-loading clip coupling gun according to an embodiment of the present invention, shown prior to loading;

FIG. 17 is an enlarged partial view of FIG. 16;

FIG. 18 is a schematic view of a side loading clip coupling gun loading according to one embodiment of the present invention;

FIG. 19 is a schematic view of a side-loading clip continuous shooting gun of one embodiment of the present invention;

FIG. 20 is a partial enlarged view of FIG. 19;

FIG. 21 is a schematic view of a portion of a side-loading clip adapter gun according to an embodiment of the present invention;

FIG. 22 is a diagram of a reel ready-to-insert state of a reel gun launcher according to a second embodiment of the present invention;

FIG. 23 is a schematic view of a rotor of a rotary gun launcher according to a second embodiment of the present invention;

FIG. 24 is a state diagram of the firing of the rotary gun launcher according to the second embodiment of the present invention;

FIG. 25 is a diagram of a reel ready-to-insert state of the internal structure of the gun launcher according to the second embodiment of the present invention;

FIG. 26 is an initial state diagram of the internal structure of the rotary gun launcher in the second embodiment of the present invention;

FIG. 27 is a diagram showing a state of rotation of a rotor in the internal structure of the gun launcher according to the second embodiment of the present invention;

FIG. 28 is a cocking state diagram of the internal structure of the rotary gun launcher in the second embodiment of the present invention;

FIG. 29 is a state diagram showing the internal structure of the rotary gun launcher according to the second embodiment of the present invention;

FIG. 30 is an internal structural view of a rotor according to a second embodiment of the present invention;

FIG. 31 is a schematic view of a pressing member according to a second embodiment of the present invention;

FIG. 32 is an initial state diagram of the pull cup and the spin column in the second embodiment of the present invention;

FIG. 33 is a view showing a state in which the pull handle and the rotary wheel of the rotary post are rotated in accordance with the second embodiment of the present invention;

FIG. 34 is an initial state view of the pull cup and linkage bar in the second embodiment of the present invention;

FIG. 35 is a view showing the rotation of the pull handle and the linkage rod in the second embodiment of the present invention;

FIG. 36 is a view showing the loading state of the pull handle and the push rod in the second embodiment of the present invention;

FIG. 37 is an initial state diagram of the push rod in the second embodiment of the present invention;

FIG. 38 is a view showing the charging state of the push rod in the second embodiment of the present invention;

FIG. 39 is a locked state view of the trigger in the second embodiment of the present invention;

FIG. 40 is an unlocked state of the trigger in the second embodiment of the present invention;

fig. 41 is a locked state diagram of the shooting pot in the second embodiment of the present invention;

fig. 42 is an unlocked state diagram of the shooting pot in the second embodiment of the present invention.

Reference symbol comparison table:

launcher 10, toy piece 20;

fig. 1 to fig. 21:

gun body 1: the device comprises a socket 11, a buckle 12, a dismounting key 13, an unlocking part 14, a gun barrel 15, a pressing spring 16 and an inclined surface 17;

the cassette 2: the clamping position 21, the locking piece 22, the unlocking groove 23, the pushing mechanism 24 and the pushing block 241;

and a loading mechanism 3: a slide plate 31, a top piece 32 and a fourth tension spring 33;

the driving mechanism 4: a second tension spring 41, a slide block 42, a tail buckle 43, a poke rod 44, a return spring 45 and a buckle groove 421;

a trigger 5: a return spring 51, a slope 52, a lock plate 53, a switching groove 54;

the blocking mechanism 6: the first tension spring 61, the side baffle plate 62, the side baffle plate buckle 63, the return spring 64, the side push plate 65, the hook 621 and the pusher dog 622;

a pull handle 7: a first connecting column 71, a shifting block 72 and a second connecting column 73;

the acceleration mechanism 8: a rack 81, a gear set 82, a third tension spring 83 and a push hook 811;

the locking mechanism 9: latch hook 91, pin 92.

Fig. 22 to 42:

gun body 01: a gun chamber 011, a rotary column 012, a sliding rod 013, a gun handle 014, a rotary wheel groove 016, a pull handle groove 017, an inclined plane 018, a shaft groove 0121, a straight groove 0122, an inclined groove 0123, a sliding groove 0131, a high groove 0131a and a low groove 0131 b;

turning wheel 02: a spring nest 021, a rotating shaft 022, a rotating rod 023 and a locking mechanism 024;

and a loading mechanism 03: a pull handle 031, a push inclined plane pin 032, a linkage rod 033, a push block 034, a push rod 035 and a top part 036;

the driving mechanism 04: ejection cartridge 041, ejection lock 042, locking piece 043, accelerator 044, accelerator gear set 045, pull ring 046;

a trigger 05;

the runner detaching mechanism 06: a pressing member 061, a first link 062, a first rack 063, a gear 064, a second rack 065, a second link 066, a key 0611, a curved bar 0612, and a push cylinder 0613;

safety lock 07: a grounding switch 071 and a limiting block 072.

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.

Toy transmitter, including the transmitter casing with can dismantle the storing casket of being connected with the transmitter casing, the storing casket is used for packing into two at least toy pieces, the toy transmitter is still including installing mechanism, actuating mechanism and the launching mechanism of going up in the transmitter casing, on the mechanism of going up is arranged in driving the actuating mechanism with the toy piece in the storing casket, actuating mechanism can accelerate the toy piece, the launching mechanism can be with the toy piece transmission after accelerating away.

The launcher housing may be a shaped housing having a pistol, or submachine gun, or revolver, or machine gun, or side-loaded clip-on pistol.

The storage box can be used for containing toy pieces such as a ball, a flying disc, a toy car, a top and the like.

The storage box is arranged in the plurality of toy pieces and is installed with the launcher shell for bringing the toy pieces into the launcher shell.

The storage box can be detachably and fixedly connected with the emitter shell, or can be rotatably connected with the emitter shell, or can be slidably connected with the emitter shell, so that the toy piece can be conveniently supplemented and filled.

The loading mechanism brings the toy piece into the launcher housing to the drive mechanism.

The driving mechanism can accelerate the toy piece, and the driving mechanism can accelerate the toy piece in a rotating mode, or accelerate ejection, or accelerate power, or any combination of several kinds of power.

The acceleration of the toy piece can be independently completed by the driving mechanism, and the driving mechanism can also act together with the loading mechanism, so that the toy piece is accelerated by the linkage of the loading mechanism and the driving mechanism.

When the launching mechanism is triggered, the launching mechanism may unlock the drive mechanism, allowing the drive mechanism to launch the toy piece.

The launched toy piece may continue to fly, travel, or spin in the air, or on the water, or on the ground, or on a track, or on a playing surface.

In some embodiments of the invention, the toy piece is driven to the drive mechanism by the loading mechanism, accelerated by the drive mechanism, and finally launched by the launching mechanism. Through loading, accelerating and launching a plurality of toy pieces one by one, continuous acceleration and continuous launching are realized, the launching efficiency is improved, a plurality of people can compete and play at the same time, and the interest and the challenge of the toy are increased.

Furthermore, an accelerating emission area is arranged in the emitter shell, a plug-in port for the storage box to be plugged in is arranged at the position of the accelerating emission area, and when the storage box is inserted into the plug-in port, a first toy piece in the storage box automatically enters the accelerating emission area.

The acceleration launching zone is a reserved space of the toy piece in the launcher shell, and the toy piece is loaded, accelerated and launched in the acceleration launching zone. After launching, the toy piece is ejected from the accelerated launch area to the outside of the launcher housing.

The interface is the connecting part of the emitter shell and the storage box, and the interface can be arranged on the top surface, the side surface, the bottom surface or the rear side of the emitter shell.

In some embodiments of the present invention, as shown in fig. 5, a propelling mechanism 24 is provided in the magazine 2 for propelling the toy pieces 20 contained in the magazine 2 toward the opening of the magazine 2;

the opening is provided with a locking piece 22 for limiting the toy pieces 20 in the opening position, when the storage box 2 is arranged in the insertion port 11, the locking piece 22 is unlocked, and the pushing mechanism 24 pushes the first toy piece 20 in the storage box 2 into the accelerating launching area.

In another embodiment of the invention, a propelling mechanism is arranged in the launcher housing for driving a magazine connected to the socket into motion, wherein when the magazine is inserted into the socket, a first toy piece automatically enters the accelerated emission region, and then the toy pieces placed at other positions in the magazine are driven to the accelerated emission region by the operation of the propelling mechanism.

In some embodiments of the invention, the storage box is provided with a clamping position, and the emitter shell is provided with a buckle and a dismounting key;

when the storage box is connected with the interface, the buckle is clamped with the clamping position;

the button is detached through pressing, so that the buckle is separated from the clamping position, and the storage box is detached.

In some embodiments of the invention, the loading mechanism comprises a pull handle and a top piece, wherein a part of the pull handle extends out of the launcher shell, and when the pull handle is pulled to move to the position of the driving mechanism, the pull handle drives the top piece to push the toy piece, so that the toy piece is connected to the driving mechanism.

The toy piece is held in a position where the driving mechanism is located, and the driving mechanism rotationally accelerates the toy piece; or the energy storage is accelerated, so that the toy piece has the ejection tendency.

The top piece may be stationary; the emitter can also be reversible and designed to be turned over, so that the space in the emitter shell can be saved.

In another embodiment of the invention, the loading mechanism can also be used as a power part of the driving mechanism, and the loading mechanism is pulled back and forth to drive the driving mechanism to continuously rotate and accelerate the toy part.

In some embodiments of the present invention, when the storage box is provided with the pushing mechanism,

the toy launcher also includes a blocking mechanism that separates the first toy piece from the remaining other toy pieces in the magazine as the loading mechanism is pulled, preventing the other toy pieces in the magazine from entering the launcher housing and interfering with the operation of the accelerated launch.

In another embodiment of the present invention, the propelling mechanism is a screw mechanism, the screw mechanism is used for driving the storage box connected to the insertion port to rotate, and the toy pieces placed at other positions in the storage box are rotated to the position of the accelerated emission area through the operation of the screw mechanism.

Specifically, as shown in fig. 25, the screw-in mechanism is a rotary column 012, the storage box is a rotating wheel 02, the rotary column 012 is used to drive the rotating wheel 02 to rotate synchronously, and each time the rotating wheel 02 rotates, one toy piece 20 is brought into a position of the accelerating launching area.

As shown in fig. 32, the loading mechanism includes a push slant pin 032, and a sliding slot is disposed on the corresponding screwing mechanism, when the loading mechanism is pulled, the push slant pin 032 is driven to move in the sliding slot, so that the screwing mechanism drives the storage box (wheel 02) to rotate, and the toy pieces at other positions of the storage box can be rotated to the position of the accelerated emission area.

Optionally, the pushing mechanism may further drive the storage box to move left and right, so as to drive the toy piece in the storage box from the left side of the launcher casing to the inside of the launcher casing, and simultaneously drive the toy piece in the inside of the launcher casing to the right side of the launcher casing.

In some embodiments of the invention, the drive mechanism has two driving forces, one is to compress the drive mechanism backwards when the toy piece is loaded, so that it has a forward ejection driving force; the other is the rotational driving force provided to the toy piece by the power piece after the toy piece is mounted.

Alternatively, the drive mechanism may also provide only a firing drive force, or a rotational drive force.

Further, the power element is an independently accelerated pull rope assembly, or a loading mechanism is used as the power element of the driving mechanism.

Further, when the loading mechanism is used as a power piece of the driving mechanism,

the driving mechanism comprises an ejection driving assembly and a rotation driving assembly which are independently arranged, the ejection driving assembly is driven by the loading mechanism to be locked in an energy storage state after energy storage, then the loading mechanism provides rotating force for the rotation driving assembly, and the ejection driving assembly is unlocked under the buckling of the launching mechanism, so that the toy piece is ejected.

The first embodiment is as follows:

as shown in fig. 1-3, the launcher 10 is a side-loading cartridge continuous shooting gun, and includes a gun body 1 and a box 2, wherein the gun body 1 is a launcher casing, and the box 2 is a storage box;

one side of the gun body 1 is provided with an interface 11, a box 2 is detachably arranged on the interface 11, the box 2 is used for accommodating at least two toy pieces 20, a propelling mechanism 24 is arranged in the box 2, and the propelling mechanism 24 is used for propelling the toy pieces 20 into the gun body 1;

the gun body 1 is internally provided with a loading mechanism 3, a driving mechanism 4 and a trigger 5, the loading mechanism 3 is used for driving the toy piece 20 in the gun body 1 to the driving mechanism 4, and the trigger 5 is a launching mechanism and used for unlocking the driving mechanism 4 to enable the driving mechanism 4 to launch the driven toy piece 20.

In this embodiment, the toy pieces 20 are toy vehicles, and a plurality of toy vehicles are loaded into the magazine 2 and are pushed into the gun body 1 one by one to be launched.

Alternatively, the toy piece 20 may be a flying disc, or a top, or a ball, etc. to be launched by the gun body 1.

When the toy pieces 20 in the magazine 2 have been fired, the magazine 2 is removed and a plurality of toy pieces 20 are loaded again, and the magazine 2 is mounted on the gun body 1.

In fig. 1 cassette 2 is mounted to gun body 1; in FIG. 2, the pull handle 7 is pulled backwards to realize the loading operation; in fig. 3, the trigger 5 is pulled to launch the toy car from the gun body 1, and the toy car flies to the ground or the game table to continue running.

As shown in fig. 6, the port 11 is opened on the side of the gun body 1, and the cassette 2 is inserted into the port 11 along the side and connected to the gun body 1.

As shown in fig. 5, the magazine 2 has a flat structure with openings opened in the side for receiving three toy vehicles, which are arranged in a row in the magazine 2. The pushing mechanism 24 is located at the bottom of the magazine 2 and applies a pushing force to the toy piece 20 to push the toy piece 20 toward the interior of the gun body 1.

Specifically, the urging mechanism 24 includes a pressing spring (not shown) and a push block 241, and the pressing spring is installed between the push block 241 and the inner wall of the cassette 2. When a plurality of toy elements 20 are loaded into the magazine 2, the toy elements 20 compress the compression springs, which tend to push the toy elements 20 outwards. When the magazine 2 is mounted to the gun body 1, the pusher 241 pushes the toy piece 20 into the gun body 1.

Further, as shown in fig. 4, a clamping position 21 is arranged on the cassette 2, and a buckle 12 and a dismounting button 13 are arranged on the gun body 1;

when the box 2 is connected with the interface 11, the buckle 12 is clamped with the clamping position 21;

the cassette 2 is removed by pressing the removal button 13 to separate the catch 12 from the catch position 21.

Specifically, the clamping position 21 is a clamping groove structure and is disposed on the bottom surface of the cassette 2.

A buckle 12 and a dismounting key 13 are arranged below the side interface 11 of the gun body 1, and a compression spring 16 is also arranged on the buckle 12.

When the box 2 is connected with the interface 11, the buckle 12 is clamped into the clamping position 21, and the pressing spring 16 pushes the buckle 12 to be pressed with the clamping position 21, so that the connection between the box 2 and the gun body 1 is realized.

When the unload key 13 is pressed down, the unload key 13 drives the latch 12 downward, the latch 12 is separated from the latch position 21, and the cassette 2 can be pulled out in the lateral direction.

Alternatively, the catch 12 and the catch position 21 can also be arranged at other positions of the gun body 1 and the cassette 2, such as: upper surface, or side surface. Locking and unlocking during plugging can also be realized in other ways.

Further, as shown in fig. 5 to 7, the cassette 2 includes a locking piece 22 and an unlocking groove 23, the locking piece 22 is slidably installed in the unlocking groove 23, and the unlocking portion 14 is provided on the gun body 1;

lock 22 blocks toy element 20 within magazine 2 before magazine 2 is installed in socket 11;

when the cassette 2 is mounted to the socket 11, the unlocking portion 14 pushes the locking member 22 into the unlocking groove 23 to unlock the toy member 20, and the unlocked toy member 20 is pushed into the gun body 1 by the pushing mechanism 24.

Specifically, as shown in fig. 5, two lock pieces 22 are provided at both ends of the opening of the cassette 2. Prior to the mounting of cassette 2 in socket 11, lock 22 is urged by a spring (not shown) towards the center of the opening, partially blocking the opening so that toy piece 20 cannot pass through the opening, preventing the removal of toy piece 20.

When the toy piece 20 is loaded into the magazine 2, the toy piece 20 pushes against the locking elements 22, pushing both locking elements 22 into the unlocking slot 23, so that the toy piece 20 can enter the interior of the magazine 2 through the opening.

As shown in fig. 6, the unlocking portions 14 are respectively provided on both sides of the insertion port 11 of the gun body 1, and the unlocking portions 14 include a slope surface which, when contacting the locking member 22, can press and push the locking member 22 toward the unlocking groove 23, so that the opening of the magazine 2 is completely opened, and the toy members 20 can be pushed into the interior of the gun body 1 by the pushing mechanism 24.

When the box 2 is detached from the gun body 1, the locking member 22 is separated from the unlocking portion 14, and the locking member 22 moves inward again under the action of the spring to partially shield the opening and lock the toy 20 inside the box 2, thereby preventing the toy 20 from falling off accidentally during detachment.

Further, as shown in fig. 8, it further comprises a blocking mechanism 6, when a toy piece 20 enters the gun body 1, the blocking mechanism 6 moves between the magazine 2 and the gun body 1 to separate the toy piece 20 in the magazine 2 from the toy piece 20 entering the gun body 1.

Specifically, the stopper mechanism 6 can slide back and forth in the longitudinal direction of the gun body 1. In the initial position, the blocking mechanism 6 is located at the front of the gun body 1, and the blocking mechanism 6 clears the passage between the cassette 2 and the interface 11.

When a toy vehicle enters the interior of the gun body 1, the blocking mechanism 6 is moved back between the magazine 2 and the interface 11, separating the first toy vehicle from other toy vehicles in the interior of the magazine 2. Preventing other toy vehicles in the magazine 2 from entering the interior of the gun body 1 while the first toy vehicle is loaded and launched.

Further, as shown in fig. 9 to 10, the blocking mechanism 6 includes a first tension spring 61, a side shutter 62, and a side shutter catch 63, and when the side shutter 62 moves between the cassette 2 and the gun body 1, the first tension spring 61 is stretched, and the side shutter 62 is locked with the side shutter catch 63;

after the trigger 5 is pulled, the trigger 5 drives the side baffle buckle 63 to separate from the side baffle 62, and the side baffle 62 returns to the initial position under the action of the first tension spring 61.

Specifically, one end of the first tension spring 61 is connected with the gun body 1, the other end is connected with the side baffle 62, and the side baffle buckle 63 is installed on the gun body 1.

As shown in fig. 9, in the initial position, the side guards 62 are positioned in front of the side guard buckles 63; as shown in fig. 10, when the side guard 62 slides backward, the first tension spring 6 is stretched, and the hook 621 at the front end of the lower side of the side guard 62 is locked with the side guard catch 63, so as to lock the side guard 62 at the position for blocking the socket 11.

Wherein, the side baffle buckle 63 is connected with a return spring 64, when the trigger 5 is buckled, the trigger 5 pushes the side baffle buckle 63 downwards, so that the side baffle buckle 63 is separated from the hook 621, and the side baffle 62 is restored to the initial position under the action of the first tension spring 61.

As shown in FIG. 11, the trigger 5 includes a return spring 51, and the return spring 51 is compressed when the trigger 5 is pulled. The trigger 5 further includes a ramp 52 and the side wall button 63 is provided with another ramp which contacts the ramp 52. When the trigger 5 is pulled, the ramp 52 pushes the side stop catch 63 downward, disengaging the catch 631. After releasing the trigger 5, the return spring 51 urges the trigger 5 to return.

Further, as shown in fig. 1-3, the charging mechanism 3 comprises a pull handle 7, the pull handle 7 slides back and forth along the barrel 15 of the gun body 1;

when the pull handle 7 slides backwards, the side baffle plate 62 is pushed to be locked with the side baffle plate buckle 63;

when the pull handle 7 slides forward, the pull handle 7 is separated from the side fence 62.

The rearward movement of the side guards 62 is carried by pulling the handle 7. The pull handle 7 is partially installed outside the gun body 1 and can slide back and forth along the length direction of the gun body 1.

Specifically, as shown in fig. 8, the pull handle 7 includes a first connecting post 71, and the first connecting post 71 is connected to the dial 72. When the pull handle 7 slides backward, the driving block 72 is also moved backward.

In the initial position, as shown in FIG. 8, the paddle 72 is spaced from the side dam 62. When the paddle 72 slides into contact with the side guards 62, the side guards 62 are pushed to slide back into a locked position with the side guard catches 73. Thereafter, the pull cup 7 can be slid forward, and the pusher 72 is separated from the side fence 62.

Further, as shown in fig. 12, an accelerating mechanism 8 is also included, and when the pull handle 7 slides back and forth along the barrel 15, the accelerating mechanism 8 is driven to accelerate the toy pieces 20 in the gun body 1.

Specifically, the acceleration mechanism 8 includes a rack 81 and a gear train 82.

As shown in fig. 8, the second connecting column 73 of the pull handle 7 is fixedly connected to the rack 81 of the acceleration mechanism 8, and when the pull handle 7 is pulled back and slides, the rack 81 is driven to move back and forth. When the rack 81 moves backward, the gear set 82 is driven to rotate, and the gear set 82 drives an acceleration gear (not shown) on the toy member 20 to rotate, so as to accelerate the toy vehicle. When the rack 81 moves forward, the rack 81 does not drive the gear set 82 to rotate, and unidirectional transmission is realized.

The pull handle 7 is pulled back and forth quickly by a player, the toy car is accelerated by the accelerating mechanism 8, and the toy car can run for a long time after being launched and falling on the ground.

The accelerating mechanism 8 further comprises a third tension spring 83, one end of the third tension spring 83 is connected with the rack 81, and the other end of the third tension spring 83 is connected with the gun body 1. When the pull handle 7 slides forward, the third tension spring 83 can provide assistance to enable the pull handle 7 and the rack 81 to move to the forefront quickly to prepare for the next acceleration.

Further, as shown in fig. 13-15, the loading mechanism 3 comprises a slide plate 31 and a top member 32, the slide plate 31 is rotatably connected with the top member 32,

in the first position, the top member 32 and the slide plate 31 are in the same plane;

in the second position, the slide plate 31 slides towards the toy element 20 in the gun body 1, the top piece 32 is flipped up relative to the slide plate 31 and contacts the toy element 20, and the top piece 32 pushes the toy element 20 to the drive mechanism 4.

Specifically, as shown in fig. 13, the slide plate 31 is slidable back and forth along the longitudinal direction of the gun body 1, one end of the third tension spring 33 is connected to the slide plate 31, and the other end of the third tension spring 33 is connected to the gun body 1. When the slide plate 31 slides backward, the third tension spring 33 is stretched.

As shown in fig. 14, before the sliding plate 31 is pushed, the top member 32 is in the same plane as the sliding plate 31, and the top member 32 and the sliding plate 31 are rotatably connected by a torsion spring (not shown). The top piece 32 is limited by the inclined surface 17 on the gun body 1, so that the top piece 32 and the sliding plate 31 are in the same plane, and the torsion spring is charged with energy.

As shown in fig. 15, when the pull handle 7 is pulled backward, the pull handle 7 pushes the side barrier 62 to move backward, the finger 622 extended from the side barrier 62 pushes the slide plate 31 to move backward, the top member 32 is driven to separate from the inclined surface 17, the top member 32 is turned upward by the torsion spring and contacts with the front end of the toy member 20, and the top member 32 pushes the toy member 20 to the driving mechanism 4.

When the trigger 5 is pulled, the trigger 5 unlocks the side guard 62, and the side guard 62 is returned under the action of the first tension spring 62. And is separated from the slide plate 31, the slide plate 31 is returned by the third tension spring 33, and the slide plate 31 and the top member 32 are again in the same plane.

Further, as shown in fig. 16-17, a locking mechanism 9 is included, such that when the toy piece 20 is pushed by the driving mechanism 4, the locking mechanism 9 locks the toy piece 20 in this position, and when the trigger 5 is actuated, the trigger 5 drives the locking mechanism 9 to unlock the toy piece 20.

Specifically, as shown in fig. 17, the locking mechanism 9 includes two locking hooks 91, and when the toy piece 20 is pushed into the driving mechanism 4, the locking hooks 91 can lock the toy piece 20 in the position, so that the acceleration mechanism 8 can accelerate the toy piece 20. In fig. 16, the toy piece 20 has not yet entered the interior of the gun body 1.

In fig. 18, the side guards 62 and the cocking mechanism 3 push the toy piece 20 into a locked position with the locking mechanism 9, while the side guards 62 push the drive mechanism 4 backwards so that the drive mechanism 4 is behind the toy piece 20.

Further, as shown in fig. 16 and 18, the driving mechanism 4 includes a second tension spring 41, a slider 42, a tail buckle 43 and a poke rod 44, when the slider 42 slides backwards, the second tension spring 41 is stretched, the slider 42 is locked with the tail buckle 43, and the poke rod 44 extends downwards from the slider 42 to the rear of the toy 20;

when the trigger 5 is pulled, the trigger 5 drives the tail buckle 43 to unlock the slide block 42, the second tension spring 41 drives the slide block 42 to move forward, and the slide block 42 ejects the toy piece 20 through the poke rod 44.

Specifically, one end of the second tension spring 41 is connected with the slide block 42, the other end is connected with the gun body 1, the rear end of the slide block 42 is provided with a catching groove 421 matched with the tail catch 43, the tail catch 43 is installed above the trigger 5 and is in contact with the trigger 5, and the position of the tail catch 43 is provided with a return spring 45.

As shown in fig. 18 and 21, a side push plate 65 is further included, and the side push plate 65 can be pushed rearward by a push hook 811 of the rack 81. When the pull handle 7 is pulled backwards, the pull handle 7 pushes the side baffle 62 and the side push plate 65, and the side baffle 62 and the side push plate 65 push the slider 42 backwards, so that the slider 42 is locked with the tail buckle 43. At this point, the push rod 44 is positioned behind the toy piece 20 and the toy piece 20 is locked by the locking mechanism 9.

As shown in fig. 19-20, when the trigger 5 is pulled, the trigger 5 brings the tail 43 upward out of engagement with the catch slot 421 for releasing the slider 42, the slider 42 is moved forward quickly by the second tension spring 41, and the push rod 44 pushes the toy piece 20.

Simultaneously, the trigger 5 drives the locking mechanism 9 to unlock the toy piece 20, the latch hook 91 is separated from the toy piece 20, and the push rod 44 ejects the toy piece 20.

Further, as shown in fig. 16, the trigger 5 further includes a lock plate 53 and a switching slot 54, two switching slots 54 are opened on the lock plate 53, a pin 92 extends from a rear end of the lock hook 91, and the pin 92 is inserted into the switching slot 54 and can move back and forth in the switching slot 54 to switch the locking and unlocking of the toy piece 20.

In fig. 16-17, the pin 92 is located at the rear end of the switching slot 54, where the distance between the locking hooks 91 is small and the locking with the toy piece 20 is enabled. But at this point the toy piece 20 has not yet entered the gun body 1.

In fig. 18, the toy piece 20 is pushed into locking engagement with the locking hook 91.

In fig. 19-20, the trigger 5 is pulled and the locking plate 53 of the trigger 5 moves backward, so that the pin 92 moves to the front end of the switching groove 54, and the distance between the two locking hooks 91 becomes larger, thereby releasing the toy piece 20.

One play method of the side-loading clip continuous shooting gun in one embodiment of the invention is as follows:

as shown in fig. 1, a magazine 2 containing a plurality of toy pieces 20 is mounted to a gun body 1, and one toy piece 20 is inserted into the gun body 1;

as shown in fig. 2, the pull handle 7 is pulled backwards, the pull handle 7 drives the loading mechanism 3 to push the toy piece 20 entering the gun body 1 to the locking mechanism 9, and the toy piece is locked by the locking mechanism 9; meanwhile, the pull handle 7 drives the side baffle 62 to shield the insertion port 11, so that the rest toy pieces 20 in the box 2 are blocked in the box 2; at the same time, the pull cup 7 also pushes the drive mechanism 4 back to the locked position.

Then, the pull handle 7 is pulled back many times and quickly, and the pull handle 7 drives the accelerating mechanism 8 to accelerate the toy 20.

When accelerated to a sufficient speed, trigger 5 is actuated, and trigger 5 unlocks the toy piece 20 and drive mechanism 4, causing drive mechanism 4 to launch the accelerated toy piece 20, as shown in fig. 3. At the same time, the trigger 5 unlocks the side guards 62 allowing the next toy piece 20 to enter the gun body 1.

Pulling the pull handle 7 once again to load the next toy piece 20;

then, the pull handle 7 is pulled to and fro again to accelerate the toy piece 20;

the trigger 5 is pulled again to launch the next toy piece 20;

this is repeated until all the toy pieces 20 in the magazine 2 have been launched;

the magazine 2 is removed and a plurality of toy pieces 20 are loaded again.

The invention can realize the continuous acceleration and the continuous launching of a plurality of toy pieces 20, thereby increasing the playability and the interest of the toy.

Example two:

as shown in fig. 22-23, the launcher 10 is a rotary pistol launcher, and includes a pistol body 01 and a rotating wheel 02, the pistol body 01 is a launcher housing, the rotating wheel 02 is a storage magazine, the rotating wheel 02 is detachably mounted on the pistol body 01, the rotating wheel 02 is provided with at least two ejection nests 021 for placing toy pieces 20, the pistol body 01 is further provided with a loading mechanism 03, a driving mechanism 04, and a trigger 05, the loading mechanism 03 is used for driving the rotating wheel 02 to rotate to a set angle relative to the pistol body 01, so that one of the ejection nests 021 is aligned with a chamber 011 of the pistol body 01, the loading mechanism 03 further drives the toy pieces 20 in the ejection nests 021 aligned with the chamber 011 to the driving mechanism 04, the trigger 05 is a launching mechanism, and when the trigger 05 unlocks the driving mechanism 04, the driving mechanism 04 ejects the toy pieces 20.

Specifically, as shown in fig. 22, the gun body 01 is in a revolver shape, the rotor 02 is in a cylindrical magazine shape, a rotor groove 016 is provided on the gun body 01, and the rotor 02 is inserted into the rotor groove 016 and can rotate relatively in the rotor groove 016.

In this embodiment, four nests 021 are provided in the wheel 02, each nest 021 being capable of receiving a toy member 20, the toy members 20 being toy vehicles. Each time the wheel 02 is rotated 90 degrees, each rotation aligns one of the nests 021 with the chamber 011 of the gun body 01, such that the toy vehicle in the nest 021 aligns with the chamber 011, facilitating subsequent launching of the toy vehicle from the chamber 011.

Alternatively, there may be two or more than two of the ammunition nests 021, and one or more than two toy pieces 20 may be placed in each ammunition nest 021, and the rotation angle of the rotating wheel 02 per time is set according to the number and distribution positions of the ammunition nests 021. The toy pieces 20 may also be spinning tops, or split discs, or pellets, etc.

In this embodiment, as shown in fig. 22, the bore 011 of the gun body 01 has a slide structure, and is disposed above the gun body 01 and extends in the longitudinal direction of the gun body 01. After the rotating wheel 02 is installed, the gun chamber 011 is communicated with the corresponding bullet nest 021, and the toy car can be ejected from the bullet nest 021 to the gun chamber 011, slides along the gun chamber 011 and finally flies out of the gun chamber 011.

As shown in fig. 22, a pull handle groove 017 is formed on the gun body 01, a pull handle 031 of the charging mechanism 03 is installed in the pull handle groove 017, and the pull handle 031 can slide along the pull handle groove 017. Pushing on the pull handle 031 causes the loading mechanism 03 to bring the toy piece 20 to the drive mechanism 04.

As shown in fig. 22, a driving mechanism 04 is provided behind the gun body 01, and the driving mechanism 04 is interlocked with a trigger 05 (see fig. 25). The gun body 01 also includes a gun grip 014 for facilitating the grip of the player. As shown in fig. 25, a trigger 05 is provided at the grip 014. As shown in fig. 24, when trigger 05 is pulled, trigger 05 unlocks drive mechanism 04, and drive mechanism 04 rapidly ejects toward the head of gun body 01, thereby ejecting toy piece 20.

When it is desired to fire a further toy piece 20, the loading mechanism 03 is operated again to rotate the wheel 02 through 90 ° again to align the next nest 021 containing the toy piece 20 with the chamber 011, and the operation is repeated to eject the next toy piece 20. Until all four toy pieces 20 in the wheel 02 are launched, the wheel 02 is removed and the four toy pieces 20 are loaded.

The rotating gun launcher 10 in the embodiment can realize fast switching and high-efficiency launching of a plurality of toy pieces 20, and improves the experience and interestingness of game competition.

Further, as shown in fig. 25, a rotating column 012 is arranged in the gun body 01, the rotating column 012 is a precession mechanism or a propulsion mechanism, after the rotating wheel 02 is installed in the gun body 01, a rotating shaft 022 of the rotating wheel 02 is connected with the rotating column 012 and synchronously rotates, the loading mechanism 03 can drive the rotating column 012 to rotate to a set angle, and at least two ejection nests 021 on the rotating wheel 02 are sequentially aligned with the gun chamber 011.

Specifically, as shown in fig. 25, the turning wheel 02 is installed in a turning wheel groove 016 of the gun body 01 from top to bottom.

As shown in fig. 26, the shaft 022 is connected to the rotary post 012, and one of the toy pieces 20 is positioned above the wheel 02.

As shown in fig. 27, when the pull handle 031 is pushed backward, the rotating column 012 can be driven to rotate, and when the pulling handle 031 is pushed backward, the rotating column 012 rotates 90 degrees once, and after the rotating column 012 is plugged with the rotating shaft 022 of the rotating wheel 02, the rotating wheel 02 is driven to rotate synchronously. At this point, the upper toy element 20 has rotated to the side and the other toy element 20 should have rotated to the top. Only one toy vehicle is shown in fig. 27, and four toy vehicles may be mounted.

The shaft 022 is retractable and can be inserted into the spin post 012 and positioned in the circumferential direction when the shaft 022 is extended. When the rotating shaft 022 retracts, the rotating shaft 022 is separated from the rotating column 012, so that the rotating wheel 01 and the gun body 01 are detached.

Further, as shown in fig. 25, the rotary post 012 is provided with a shaft slot 0121, into which the rotary shaft 022 is inserted;

the wheel gun launcher 10 further comprises a wheel dismounting mechanism 06, the wheel dismounting mechanism 06 is connected with the rotating shaft 022, and when the wheel dismounting mechanism 06 is pressed, the wheel dismounting mechanism 06 drives the rotating shaft 022 to be separated from the shaft groove, so that the wheel 02 is separated from the gun body 01.

Further, as shown in fig. 30 to 31, the wheel detaching mechanism 06 includes a pressing member 061, a first link 062, a first rack 063, a gear 064, a second rack 065, and a second link 066, the first link 062 being connected to the first rack 063, the gear 064 being engaged with the first rack 063 and the second rack 065, the second rack 065 being connected to the second link 066, and the second link 066 being connected to the rotation shaft 022;

when the pressing member 061 is pressed, the first connecting rod 062 is pushed, the first connecting rod 062 pushes the first rack 063 forward, the first rack 063 drives the gear 064 to rotate, the gear 064 drives the second rack 065 to retract, the second rack 065 drives the rotating shaft 022 to retract through the second connecting rod 066, and the rotating shaft 022 is disengaged from the shaft slot 0121.

Specifically, the pressing member 061 is installed at one side of the gun body 01 and is located behind the rotary wheel groove 016. The pressing member 061 includes a button 0611, a curved lever 0612, and a push cylinder 0613, and the button 0611 extends to the outside of the gun body 01, thereby facilitating the pressing by the player. The key 0611 is connected with one end of a curved bar 0612, the other end of the curved bar 0612 extends into the turning wheel groove 016, and the push cylinder 0613 is connected with the other end of the curved bar 0612.

When the key 0611 is pressed, the curved rod 0612 is driven, the curved rod 0612 pushes the push cylinder 0613 toward the first link 062, and the first link 062 protrudes outward to contact the push cylinder 0613. The push cylinder 0613 pushes the first link 062 toward the gear 064, the first link 062 drives the first rack 063 to move forward (left side in fig. 30), the first rack 063 drives the gear 064 to rotate counterclockwise in fig. 30, the gear 064 drives the second rack 065 to move backward (right side in fig. 30), the second rack 065 drives the second link 066 to move backward, and the second link 066 drives the rotating shaft 022 to retract backward, so that the rotating shaft 022 is disengaged from the shaft groove 0121, and the rotating wheel 02 can be removed from the gun body 01.

Wherein, return spring 066 is installed on both first link 062 and second link 065, and when key 0611 is released, return spring 066 drives first link 062 and second link 065 to return.

Further, as shown in fig. 32-33, the loading mechanism 03 includes a pull handle 031 and a push inclined plane pin 032, and at least two sets of straight slots 0122 and inclined slots 0123 are provided on the rotary column 012;

the pull handle 031 pushes the push bevel pin 032 to be in front of, and the push bevel pin 032 is positioned in the straight slot 0122;

when the handle 031 is pulled to push away inclined plane pin 032, push away inclined plane pin 032 and enter into the chute 0123 with straight flute 0122 in the same group to drive column spinner 012 to turn to the angle of settlement, column spinner 012 drives runner 02 to rotate together.

Specifically, four groups of straight slots 0122 and inclined slots 0123 are arranged on the rotary column 012, and when the inclined plane pushing pin 032 slides along one group of straight slots 0122 and inclined slots 0123 at a time, the rotary column 012 rotates 90 °. As shown in fig. 32, the straight trough 0122 is connected to the inclined trough 0123 'of one group from left to right (see fig. 32), then the straight trough 0122 continues to extend to right, and is connected to the inclined trough 0123 of the same group, the inclined trough 0123 is inclined from top to bottom and from right to left, and the lower end of the inclined trough 0123 is connected to the straight trough 0122' of the next group (see fig. 33).

As shown in FIG. 32, before the pull handle 031 is pushed, the push-slant pin 032 is located in the straight slot 0122. When the pull handle 031 is pushed backward, the pull handle 031 drives the push slant pin 032 to slide along the straight slot 0122, and the push slant pin 032 slides from the straight slot 0122 to the slant slot 0123 along the arrow direction in fig. 32. Because the inclined plane pushing pin 032 only slides along the straight line, the rotating column 012 is pushed to rotate when the inclined plane pushing pin 032 slides along the inclined slot 0123.

As shown in fig. 33, the pull handle 031 continues to push, and the push slope pin 032 slides from the oblique slot 0123 into the next group of straight slots 0122 'and enters the rearmost end of the straight slots 0122', and the rotary post 012 has now rotated 90 °.

When the pull handle 031 is loosened, the push inclined pin 032 returns under the action of the return spring, i.e., slides to the foremost end of the straight slot 0122' in the direction of the head of the gun body 01, so as to prepare for driving the rotary column 012 next time.

Further, as shown in fig. 32-35, the loading mechanism 03 further includes a linkage rod 033, a push slope pin 032 is fixedly connected with one end of the linkage rod 033, and the other end of the linkage rod 033 is connected with a push block 034;

the gun body 01 comprises a sliding rod 013, a sliding groove 0131 is formed in the sliding rod 013, a pushing block 034 is installed in the sliding groove 0131, a pulling handle 031 pushes the pushing block 034 to slide along the sliding groove 0131 when sliding along the sliding rod 013, the pushing block 034 drives a linkage rod 033, and the linkage rod 033 drives a pushing slope pin 032 to slide in a straight groove 0122 and a skewed groove 0123.

Specifically, the linkage rod 033 is connected to the push slope pin 032, and the other end of the linkage rod 033 extends into the chute 0131 and contacts with the push block 034. A projection 0311 extends from the middle of the pull handle 031, and the projection 0311 contacts with the push block 034.

As shown in fig. 34, before the pull handle 031 is pushed, the push block 034 is located at the front end of the sliding slot 0131 (i.e., the right side of fig. 34).

As shown in fig. 35, when the pull handle 031 is pushed, the push block 034 pushes backward (i.e. to the left in fig. 35) along the chute 0131, and during the process of pushing backward by the push block 034, the linkage rod 033 is driven to move backward, and the linkage rod 033 drives the push slope pin 032 to slide backward.

Further, as shown in fig. 34 to 35, the chute 0131 includes a high-level groove 0131a and a low-level groove 0131 b;

when the push block 034 slides along the elevated groove 0131a, the push inclined pin 032 slides along the straight groove 0122;

when the push block 034 slides into the low slot 0131b from the high slot 0131a, the push inclined pin 032 slides downward into the inclined slot 0123 from the straight slot 0122, and the rotary post 012 rotates to a set angle.

As shown in fig. 34, the height of the high-level slot 0131a is higher than that of the low-level slot 0131b, and when the push block 034 slides into the low-level slot 0131b from the high-level slot 0131a, the push block 034 sinks, and the push block 034 drives the push inclined plane pin 032 to sink, so that the push inclined plane pin 032 can slide into the inclined slot 0123 from the straight slot 0122.

Further, as shown in fig. 37-38, the loading mechanism 03 includes a pull handle 031 and a push rod 035, and the pull handle 031 drives the push rod 035 to drive the toy pieces 20 to the driving mechanism 04.

Specifically, as shown in fig. 38, the front end of the push rod 035 is rotatably connected to the top 036. A torsion spring is connected between the top part 036 and the push rod 035. Before the handle 031 is pulled, the top 036 is constrained by the bevel 018 of the gun body 01, so that the top 036 is flush with the push rod 035, and a certain distance is left between the top 036 and the toy element 20.

As shown in fig. 38, when push rod 035 is pushed rearward by handle 031, push rod 035 pushes against tip 036, disengaging tip 036 from ramp 018, tip 036 flips upward relative to push rod 035, tip 036 contacts toy piece 20 as push rod 035 is pushed rearward, and pushes toy piece 20 toward drive mechanism 04.

Further, as shown in fig. 36, the wheel 02 includes a lever 023 and a locking mechanism 024, the locking mechanism 024 for locking the toy piece 20 in the wheel 02;

when the handle 031 pushes the push rod 035, the push rod 035 drives the rotating rod 023 to rotate, the rotating rod 023 drives the locking mechanism 024 to unlock with the toy 20, so that the push rod 035 can drive the toy 20 to the driving mechanism 04.

In this embodiment, the lever 023 and the locking mechanism 024 are in four sets, one set in each nest 021 for locking and unlocking the corresponding toy piece 20. When a toy piece 20 is inserted into the nest 021, a locking mechanism 024 locks the toy piece 20 in the nest 021. The rotary lever 023 has one end in contact with the locking mechanism 024 and the other end extending toward the gun body 01, and a rotary shaft (not shown) is provided at the center of the rotary lever 023. When the push rod 035 contacts the other end of the rotary lever 023, the rotary lever 023 is pushed to rotate, and one end of the rotary lever 023 pushes the locking mechanism 024 downwards, so that the locking mechanism 024 is separated from the toy piece 20, and the toy piece 20 is unlocked.

After the toy element 20 is unlocked, the push rod 035 simultaneously pushes the toy element 20 through the head 036 to the drive mechanism 04.

Further, as shown in FIGS. 39-40, the drive mechanism 04 includes a shoot cartridge 041 and a shoot lock 042;

when the toy member 20 is driven to the driving mechanism 04, the ejection lock 042 locks the ejection cylinder 041, and the ejection cylinder 041 contacts the toy member 20;

when the trigger 05 is pulled, the trigger 05 drives the ejection lock 042 to unlock the ejection cartridge 041, and the ejection cartridge 041 ejects the toy piece 20.

Specifically, as shown in fig. 39-42, the drive mechanism 04 further includes a locking member 043, an accelerator member 044, an accelerator gear set 045, and a pull ring 046.

As shown in FIG. 41, the lock car member 043 is mounted in the cartridge 041 so as to be able to extend into the cartridge 041 or retract into the cartridge 041. When the car locking member 043 is extended, the toy member 20 is locked, holding the toy member 20 in a position in which the cartridge 041 is in contact.

The ejection lock component 042 locks the ejection barrel 041 and keeps the ejection barrel 041 in an energy storage state; when the ejector lock 042 releases the ejector cartridge 041, the ejector cartridge 041 moves forward quickly, ejecting the toy piece 20 at the same time.

When the barrel 041 is locked and moved rearward, the accelerator 044 extends into the barrel 041, and the accelerator 044 is coupled to the toy vehicle to accelerate the toy vehicle.

The accelerating member 044 is driven by an accelerating gear set 045, and the accelerating gear set 045 is driven by a pull ring 046 to accelerate through a pull rope (not shown).

When the toy vehicle is accelerated to a desired speed, trigger 05 is pulled and trigger 05 drives ejection lock 042 to unlock ejection cartridge 041.

As shown in FIG. 42, the ejection cartridge 041 is accelerated forward and ejected, the latch member 043 is retracted into the ejection cartridge 041 for releasing the toy member 20, and the ejection cartridge 041 ejects the toy member 20.

Further, as shown in fig. 39-40, a safety lock 07 is provided in the gun handle 014, and the safety lock 07 includes a grounding switch 071 and a limiting block 072.

As shown in fig. 39, the grounding switch 071 extends from the lower end of the gun handle 014 under the action of its own weight, the upper end of the grounding switch 071 contacts with the limiting block 072, the limiting block 072 is used for limiting the trigger 05, and at this time, the trigger 05 cannot be pulled.

As shown in fig. 40, when the grip 014 is placed on the ground or game table, the grounding switch 071 retracts into the grip 014, the grounding switch 071 drives the limit block 072 downward, and the limit block 072 releases the limit on the trigger 05. The trigger 05 can be pulled, and after the trigger 05 is pulled, the ejection lock 042 is driven to move forward, and the ejection lock 042 unlocks the ejection barrel 041.

In one embodiment of the present invention, one of the play methods of the revolver launcher 10 is as follows:

as shown in fig. 25, the insertion state is prepared for the rotating wheel: the turning wheel 02 can be inserted into the turning wheel groove 016 of the gun body 01 from top to bottom along the hollow arrow direction.

As shown in fig. 26, the initial state is: the rotating wheel 02 is installed in the gun body 01, the rotating shaft of the rotating wheel 02 is connected with the rotating column 012, the toy element 20 in the rotating wheel 02 is not contacted with the ejection barrel 041, and the pull handle 031 is positioned at the forefront end and keeps a certain distance with the push rod 035.

As shown in fig. 27, the turning wheel is in a turning state: the pull handle 031 is pushed backward for a first stroke, the pull handle 031 drives the push rod 035, and the push rod 035 drives the rotary post 012 to rotate 90 °.

As shown in fig. 28, in the loaded state: the pull handle 031 is pushed backward to a second stroke, the pull handle 031 unlocks the locking mechanism 024 in the rotating wheel 02 by the push rod 035, the unlocked toy piece 20 is pushed by the push rod 035 to the driving mechanism 04, the toy piece 20 is locked at the driving mechanism 04, and the driving mechanism 04 can accelerate the toy piece 20.

As shown in fig. 29, in the transmission state: trigger 05 is pulled, trigger 05 unlocks the ejection cartridge 041, and ejection cartridge 041 ejects toy piece 20. The pull handle 031 and the push plate 035 return to the initial state.

When it is desired to fire a further toy element 20, the operations of fig. 27 to 29 are repeated a plurality of times until all of the toy elements 20 have been fired, the button 0611 is depressed, the reel 02 is removed from the gun body 01, and four toy elements 20 are again loaded.

The invention can realize continuous launching of a plurality of toy pieces, improves the launching efficiency of the toy gun, can be played by a plurality of persons simultaneously, and increases the interest and the challenge of the toy.

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 (12)

1. The utility model provides a toy transmitter, its characterized in that, including the transmitter casing and with the storage casket of connection can be dismantled to the transmitter casing, the storage casket is used for packing into two at least toy spares, the toy transmitter is still including installing mechanism of borduring, actuating mechanism and the firing mechanism in the transmitter casing, mechanism of borduring is used for with in the storage casket the toy spare drives on the actuating mechanism, actuating mechanism can be right the toy spare is accelerated, the firing mechanism can with after accelerating the toy spare is launched.

2. The toy launcher according to claim 1, wherein an accelerated launching zone is provided in the launcher housing, a socket for receiving the magazine is provided at the accelerated launching zone, and when the magazine is inserted into the socket, a first of the toy pieces in the magazine automatically enters the accelerated launching zone.

3. The toy launcher according to claim 2, wherein a propelling mechanism is provided in said magazine for propelling said toy pieces contained in said magazine in a direction of an opening of said magazine;

the opening part is provided with a locking piece for limiting the toy piece at the opening position, when the storage box is arranged in the insertion port, the locking piece is unlocked, and the pushing mechanism pushes the first toy piece in the storage box into the accelerating launching area.

4. The toy launcher according to claim 3, further comprising a blocking mechanism that separates a first of said toy pieces from other toy pieces remaining in said magazine as said loading mechanism is pulled.

5. The toy launcher of claim 2, wherein a propulsion mechanism is provided in the launcher housing for moving the magazine coupled to the docking port, wherein when the magazine is inserted into the docking port, a first of the toy pieces automatically enters the accelerated launch area, and thereafter the toy pieces placed elsewhere in the magazine are moved to the accelerated launch area by operation of the propulsion mechanism.

6. The toy launcher according to claim 5, wherein the propelling mechanism is a precession mechanism for rotating the magazine coupled to the socket, the toy member placed elsewhere in the magazine being rotated to the accelerated emission zone by operation of the precession mechanism.

7. The toy launcher according to claim 6, wherein the loading mechanism includes a push ramp pin, and the corresponding screwing mechanism is provided with a sliding slot, and when the loading mechanism is pulled, the push ramp pin is driven to move in the sliding slot, so that the screwing mechanism drives the magazine to rotate.

8. The toy launcher according to claim 2, wherein a snap-fit location is provided on the storage pocket, and a snap and a removal button are provided on the launcher housing;

when the storage box is connected with the interface, the buckle is clamped with the clamping position;

the button is detached through pressing, so that the buckle is separated from the clamping position, and the storage box is detached.

9. The toy launcher of claim 1, wherein the loading mechanism includes a pull handle and a top member, the pull handle partially extending outside the launcher housing, the pull handle driving the top member to push the toy member when the pull handle is pulled to move to the position of the driving mechanism, such that the toy member is coupled to the driving mechanism.

10. The toy launcher according to claim 1, wherein said driving mechanism has two driving forces, one being a forward ejection driving force by compressing said driving mechanism backwards when said toy piece is installed; the other is a rotational driving force provided to the toy piece by a power member after the toy piece is mounted.

11. The toy launcher according to claim 10, wherein the motive member is an independently accelerating pull string assembly, or the cocking mechanism is the motive member of the drive mechanism.

12. The toy launcher according to claim 11, wherein when the loading mechanism is used as a power element of the driving mechanism,

the driving mechanism comprises an ejection driving assembly and a rotation driving assembly which are independently arranged, the ejection driving assembly is driven by the loading mechanism to store energy and then can be locked in an energy storage state, the loading mechanism provides rotating force for the rotation driving assembly, and the ejection driving assembly is unlocked under the buckling of the launching mechanism, so that the toy piece is ejected.

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