CN111389025A - Gyro gun - Google Patents

Abstract

The application discloses a spinning top gun, which comprises a gun body and a magazine detachably mounted on the gun body, wherein the magazine is used for loading at least two spinning tops; the gun body comprises a driving handle, a triggering assembly and a driving position, one gyro in the magazine can fall into the driving position through the driving handle, the gyro positioned in the driving position can be rotationally accelerated, and finally the gyro is ejected out of the gun body through triggering the triggering assembly. The utility model provides a top rifle, a plurality of tops can be packed into in the magazine, only need operation drive handle and trigger assembly just can realize the upper chamber of top, accelerate and launch, easy operation launches a top after, and repetitive operation just can launch next top, makes the top possess the play method of toy gun, improves the object for appreciation nature of top.

Description

Gyro gun

Technical Field

The application relates to the technical field of spinning top toys, in particular to a spinning top gun.

Background

The top is a rotating toy with a round upper part and a tip extending from the lower end, and can rotate at high speed with the tip as a fulcrum after applying a rotating force. Current mainstream top toy is mainly for top toy accelerates through hand power rack or rope, later launches the top, makes the top rotate at a high speed to most top toy's transmission seat can only install a top, and the single can only launch a top, later just will install the top again and launch again, can't launch a plurality of tops in succession, leads to top toy's interest lower. Therefore, a gyro gun capable of loading a plurality of gyros and continuously launching the plurality of gyros needs to be provided.

Disclosure of Invention

The utility model aims to overcome prior art's not enough, provides a plurality of tops of can packing into, realizes the top rifle of a plurality of tops of continuous transmission.

The technical scheme of the application provides a spinning top gun, which comprises a gun body and a magazine detachably mounted on the gun body, wherein the magazine is used for loading at least two spinning tops;

the gun body comprises a driving handle, a triggering assembly and a driving position, one gyro in the magazine can fall into the driving position through the driving handle, the gyro positioned in the driving position can be rotationally accelerated, and finally the gyro is ejected out of the gun body through triggering the triggering assembly.

Furthermore, the gun body further comprises a loading assembly and a driving piece for placing and driving the top to launch, the loading assembly and the driving piece are in linkage fit with the driving handle, and the driving position is located on the driving piece; when the driving handle is driven,

firstly triggering the loading assembly to grab one gyro in the magazine to be placed on the driving piece;

then the driving part is driven to drive the gyroscope on the driving position to rotate and accelerate.

Further, the trigger assembly is used for locking and triggering the driving piece;

when one of the gyros in the magazine falls into the driving position, the triggering assembly locks the driving piece;

and when the trigger assembly is triggered, unlocking the driving piece to launch the spinning top.

Further, the driving piece can slide between a first position close to the magazine and a second position far away from the magazine under the driving of the driving handle in a reciprocating mode, and the gyro gun is in different states when the driving piece and the driving handle are in different positions and actions, wherein,

standby state: when the driving piece is at the second position, the gyro gun is in a standby state;

loading state: when the driving handle is driven to slide towards a first position for the first time, the driving handle pushes the driving piece to slide towards the loading assembly and trigger the loading assembly, meanwhile, the driving piece is locked at the first position, and then the driving handle slides towards a second position;

an acceleration state: when the driving handle is driven to slide towards the magazine again, the driving handle drives the gyroscope on the driving piece to rotate and accelerate;

and (3) a transmitting state: when the trigger assembly is triggered, the driving piece is unlocked to slide to the second position and the spinning top is launched.

Further, the driving handle comprises a handle shell and a push rod connected to the inside of the handle shell, the handle shell is exposed outside the gun body, the push rod is located in the gun body and movably arranged along the length direction of the gun body, the handle shell drives the push rod to move synchronously when being driven, and the push rod is used for pushing the driving piece to slide towards the first position and driving the gyroscope to rotate and accelerate.

Furthermore, the gun also comprises a gyro accelerator which is fixed in the gun body, and the push rod is matched with the gyro accelerator;

the driving part is including supplying the top seat that the top was placed, but the top seat is connected relatively rotation ground on the driving part, top seat lower extreme be equipped with rotary gear with top accelerator meshing, the acceleration state, the push rod is followed length direction reciprocating motion of the rifle body drives the top accelerator lasts for top seat and be located top rotation on the top seat accelerates.

Furthermore, the driving piece is installed in the gun body through the driving elastic piece, the driving elastic piece stores energy when the triggering assembly locks the driving piece, and the driving elastic piece releases energy when the triggering assembly unlocks the driving piece to drive the driving piece to slide from the first position to the second position.

Furthermore, the driving piece also comprises a thimble, and the thimble is positioned at the bottom of the driving position and can move in the direction that the gyro is separated from the driving piece;

the front end of the gun body is provided with a launching guide surface which gradually inclines upwards towards the direction that the gyro is ejected out of the gun body, and when the lower end of the driving piece slides to the launching guide surface, the ejector pin is guided by the launching guide surface and is jacked upwards to push the gyro out of the gun body.

Further, the loading assembly is positioned between the magazine and the driving member, and the radial direction of the top in the magazine is perpendicular to the length direction of the gun body;

when the driving piece triggers the loading assembly, the loading assembly grabs a top at the foremost end in the magazine and swings to the radial direction of the top to be parallel to the length direction of the gun body, and the top is placed on the driving position of the driving piece.

Further, the loading assembly comprises a lantern ring, a rotary pushing piece and a lantern ring energy storage piece, the rotary pushing piece is connected to the lower end of the lantern ring, and the lantern ring energy storage piece is connected between the lantern ring and the rotary pushing piece;

when the driving handle is driven, the driving handle drives the driving piece to push the rotary pushing piece, the rotary pushing piece drives the lantern ring to swing from a preparation position which is radially vertical to the length direction of the gun body to a loading position which is radially parallel to the length direction of the gun body, and meanwhile, the lantern ring energy storage piece stores energy;

when the energy storage component releases energy, the lantern ring is driven to swing from the loading position to the preparation position.

Further, still install on the lantern ring and be used for with the top locking in the lantern ring latch fitting in the lantern ring, the lantern ring pendulum is changeed to when going up the thorax position, lantern ring latch fitting is right the top unblock, the top drops the driving piece on the drive position.

Further, the loading assembly further comprises a top stopper rotatably mounted between the collar and the magazine;

when the driving handle drives the driving piece, part of the top stopper is pushed to be shielded between the lantern ring and the magazine.

Further, the trigger assembly comprises a trigger and a driving lock rod which are in linkage fit;

when the driving handle is driven and the driving handle pushes the driving piece to slide to the position of the driving lock rod, the driving lock rod locks the driving piece;

when the trigger is triggered, the trigger pushes the driving lock rod to unlock the driving piece.

Further, the magazine comprises a magazine barrel for loading at least two gyros and a gyro lock and an elastic pushing piece which are arranged in the magazine barrel;

the elastic pushing piece is arranged in the magazine barrel and used for pushing the spinning top to the opening position of the magazine barrel;

the top lock is positioned at the opening position of the magazine barrel, and the top lock is used for locking the top in the magazine barrel;

when the top lock is triggered, the top is unlocked, and the elastic pushing piece pushes the top at the foremost end out of the magazine barrel.

Further, the top lock comprises a locking buckle and a striking piece, wherein a part of the locking buckle movably extends into the magazine barrel and is used for locking the top in the magazine barrel, and the striking piece is in linkage fit with the locking buckle and partially extends out of the magazine barrel;

when the striking piece is triggered, the locking buckle releases the locking of the spinning top, and the elastic pushing piece pushes the spinning top out of the opening of the magazine barrel.

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

according to the gyro gun, the plurality of gyros can be loaded into the magazine, the driving handle can enable one gyro to fall into the driving position and realize the rotation acceleration of the gyro, the high-speed rotating gyro is launched out through the triggering assembly, loading, acceleration and launching of the gyro can be realized only by operating the driving handle and the triggering assembly, the operation is simple, after one gyro is launched out, the next gyro can be launched through repeated operation, the gyro has the play method of a toy gun, and the play performance of the gyro is improved; moreover, this magazine can be dismantled from the rifle body, then carries out the top to the magazine and packs, pegs graft the magazine with the magazine and can realize the rifle body and launch the top in the magazine during the use on the rifle body, use more convenient and fast, imitative rifle effect is more lifelike, makes the player possess the dual experience of playing the rifle and playing the top.

Drawings

The disclosure of the present application 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 application. In the figure:

FIG. 1 is a schematic view of a gyroscopic gun according to an embodiment of the present invention;

FIG. 2 is a first schematic diagram of an internal structure of a gyro gun according to an embodiment of the present invention;

FIG. 3 is a second schematic diagram of the internal structure of the gyro gun according to an embodiment of the present invention;

FIG. 4 is a third schematic diagram of the internal structure of the gyro gun in an embodiment of the present invention;

FIG. 5 is a fourth schematic diagram of the internal structure of the gyro gun in an embodiment of the present invention;

FIG. 6 is a diagram illustrating an internal structure of a gyro gun according to an embodiment of the present invention;

FIG. 7 is a schematic diagram of the components of a gyro gun in accordance with an embodiment of the present invention;

FIG. 8 is an exploded view of the components shown in FIG. 6 in one embodiment of the present invention;

FIG. 9 is an exploded view of the driving member in one embodiment of the present invention;

figure 10 is an exploded view of the loading assembly and magazine in one embodiment of the invention;

FIG. 11 is an exploded view of the collar and its peripheral components in accordance with one embodiment of the present invention;

FIG. 12 is a schematic view of the collar in a ready position in accordance with an embodiment of the invention;

FIG. 13 is a schematic view of the collar in a loaded position in accordance with an embodiment of the present invention;

FIG. 14 is a schematic view of a collar front lock locking collar in accordance with an embodiment of the present invention;

FIG. 15 is an exploded view of a collar front lock in an embodiment of the invention;

figure 16 is a schematic view of a magazine according to an embodiment of the invention;

FIG. 17 is a cross-sectional view taken along line A-A of FIG. 16;

figure 18 is an exploded view of the magazine in one embodiment of the invention;

figure 19 is an exploded view one of the top locks of the magazine in accordance with one embodiment of the present invention;

figure 20 is a second exploded view of the top lock of the magazine in accordance with one embodiment of the present invention;

figure 21 is a schematic view of the internal structure of the magazine in accordance with one embodiment of the present invention.

Reference symbol comparison table:

the magazine 001:

the magazine barrel 101: the magazine comprises a left magazine shell 1011, a right magazine shell 1012, a bottom plate 111, a mounting column 112, a mounting groove 1121, a supporting part 1122, an elastic limiting block 113, a limiting guide surface 1131, a limiting elastic part 114, an unlocking key 115, a limiting guide column 1151, a key elastic part 116, a magazine sliding track 117 and a partition plate 118;

the gyro lock 102: the locking buckle 121, the buckle guide 1211, the striking piece 122, the through cavity 1221, the buckle guide surface 1222, the top lock shell 123, the buckle elastic piece 124 and the trigger elastic piece 125;

the elastic pushing piece 103: the push plate 131, the boss 1311, the cavity 1312, the front retainer 1313, the rear retainer 1314, the push column 132 and the push column elastic piece 133;

a top spring 104;

a gyroscope 002;

cocking assembly 003:

the lantern ring 311, the swing portion 3111, the guide convex block 3112, the rotary push piece 312, the push portion 3121, the rotating shaft connecting portion 3122, the perforation 3123, the lantern ring energy storage piece 313, and the lantern ring rotating shaft 314;

a collar guide groove 303;

collar lock 300:

upper collar lock 304: an upper locking piece housing 341, an upper front locking piece 342, an upper rear locking piece 343, an upper front elastic piece 344, and an upper rear elastic piece 345;

lower collar lock 305: a lower lock housing 351, a support hook 3511, a lower front lock 352, a lower rear lock 353, a lower front elastic member 354, and a lower rear elastic member 355;

an upper lock guide groove 306;

top stopper 307: an upper stop part 371, a lower swing part 372, a stop rotating shaft 373 and a stop twisting part 374;

the collar front lock 308, the vertical swivel 381, the transverse swivel 382, the front lock 383, the vertical swivel 384, the transverse swivel 385, the front lock twist 386, and the front lock accumulator 387.

The driving handle 004:

the handle comprises a handle shell 401, a push rod 402, a first push rod 421, a second push rod 422, a push block 423, a push rod elastic piece 424, a gyro accelerator 403, an accelerator shell 431, a gear set 432 and a rack 433;

the trigger assembly 005:

a trigger 501, a trigger guide surface 511, a driving lock lever 502, a lock lever guide surface 521, a lock lever elastic member 503, and a trigger elastic member 504;

driving member 006:

the top seat 601, the thimble 611, the rotary gear 612, the driving elastic piece 603, the driving top block 604, the front lock push plate 605, the upper driving plate 606, the lower driving plate 607, the elastic bump 608, the bump 681 and the bump elastic piece 609;

the gun body 007:

a swash block 701, a launching guide surface 711, a launching plane 712, a swash block mounting rod 702.

Detailed Description

Embodiments of the present application are further described below with reference to the accompanying drawings.

It is easily understood that according to the technical solutions of the present application, those skilled in the art can substitute various structures and implementations without changing the spirit of the present application. Therefore, the following detailed description and the accompanying drawings are merely illustrative of the technical solutions of the present application, and should not be construed as limiting or restricting the technical solutions of the present application in their entirety.

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.

The invention provides a spinning top gun, as shown in fig. 1-5, comprising a gun body 007 and a magazine 001 detachably mounted on the gun body 007, wherein the magazine 001 is used for accommodating at least two spinning tops 002;

the gun body 007 comprises a driving handle 004, a triggering assembly 005 and a driving position, one gyro 002 in the magazine 001 can fall into the driving position through the driving handle 004, the driving handle 004 is pulled again to rotate and accelerate the gyro 002 in the driving position, and finally the gyro 002 is ejected out of the gun body 007 through the triggering assembly 005.

Specifically, the magazine 001 is detachably mounted in the gun body 007, so that the loading of the spinning top 001 is facilitated, the loading operation of the toy gun is simulated, and the interestingness is high.

After the gun body 007 is loaded with the magazine 001, when the driving handle 004 is operated for the first time, one spinning top 002a in the magazine 001 can fall to the driving position, which is similar to the loading operation of a toy gun, and the spinning top gun is shown in fig. 4 after the spinning top is loaded; afterwards, the driving handle 004 is pulled to drive the gyroscope 002a on the driving position to rotate at a high speed, the gyroscope 002a is emitted out through the trigger assembly 005, the emission process is as shown in fig. 5, and after the gyroscope 002a is separated from the gun body 007, when the tip of the gyroscope 002a falls on a plane, the gyroscope 002a can keep rotating stably.

After the gyro gun emits one gyro 002 each time, the gyro gun is restored to the state before emission, and the operation is executed again, so that the next gyro 002 can be emitted. When all the gyros 002 in the magazine 001 are launched, the magazine 001 can be detached from the gun body 007, the magazine 001 is refilled with bullets (namely, gyros 002), the magazine 001 is inserted into the gun body 007 after being refilled, and the gun body 007 can be operated again to launch the gyros 002.

The gyro gun is similar to a toy gun in shape, has playing methods of 'loading', 'loading' and 'launching', and the trigger component 005 can also be set to be in the shape of a trigger, so that the gyro gun has strong interestingness.

Further, the gun body 007 further comprises a loading assembly 003 and a driving piece 006 for placing and driving the top 002 to emit, wherein the loading assembly 003 and the driving piece 006 are in linkage fit with the driving handle 004, and the driving position is located on the driving piece 006; when the driving handle 004 is driven,

firstly, triggering the loading assembly 003 to grab one gyro 002 in the magazine 001 to be placed on the driving position of the driving piece 006;

then, the driving member 006 is driven to drive the gyro 002 on the driving position to rotate and accelerate.

Specifically, as shown in fig. 2, the magazine 001 is mounted on the gun body 007 with the top 002a not loaded. At this time, the drive handle 004 is driven to trigger the loading assembly 003 to load, the loading assembly 003 picks up the gyro 002a in the magazine 001, and the gyro 002a is placed on the drive position of the drive piece 006 to complete loading of the gyro 002a, and the loaded state is as shown in fig. 4; then, the driving handle 004 drives the gyroscope 002a on the driving member 006 to rotate and accelerate, so that the gyroscope 002a rotates at a high speed, and then the triggering component 005 is triggered to emit the gyroscope 002 a.

Further, the trigger assembly 005 is used for locking and triggering the driving member 006, when one gyro 002 in the magazine 001 falls into the driving position, the trigger assembly 005 locks the driving member 006, and when the trigger assembly 005 is triggered, the unlocking driving member 006 launches the gyro 002.

Specifically, as shown in fig. 4, when the driving handle 004 is driven, the driving member 006 is locked at the position by the triggering component 005 while the top 002a falls into the driving member 006, and the driving member 006 is charged; until the triggering component 005 is triggered, as shown in fig. 5, the triggering component 005 unlocks the driving component 006, and the driving component 006 releases energy to drive the gyro 002a to slide along the length direction of the gun body 007, so that the gyro 002a is emitted out of the gun body 007.

Further, the driving member 006 is reciprocally slidable between a first position close to the magazine 001 and a second position far from the magazine 001 by the driving handle 004, and the spinning top gun is in different states at different positions and actions of the driving member 006 and the driving handle 004, wherein,

standby state: the gyro gun is in a standby state when the driving member 006 is at the second position;

cocked state (see fig. 4): upon first actuation of the actuation handle 004 to slide toward the first position, the actuation handle 004 pushes the drive member 006 to slide toward the cocking assembly 003 and triggers the cocking assembly 003 while the drive member 006 is locked in the first position, after which the actuation handle 004 slides toward the second position;

an acceleration state: when the driving handle 004 is driven to slide towards the first position again, the driving handle 004 drives the gyro 002a on the driving piece 006 to rotate and accelerate;

emission state (see fig. 5): when the trigger assembly 005 is triggered, the unlocking driving member 006 slides to the second position and ejects the top 002 a.

Specifically, referring to fig. 2-5, the magazine 001 and the driving handle 004 are respectively mounted at both ends of the gun body 007 in the longitudinal direction, and the loading assembly 003, the trigger assembly 005 and the driving member 006 are located between the magazine 001 and the driving handle 004, i.e., the "barrel" position of the gyro gun. The drive knob 004 and drive member 006 slide within the "barrel" along which the spinning top 002 is also launched. In this embodiment, the direction a from the magazine 001 to the driving handle 004 is the forward direction, and the direction b from the driving handle 004 to the magazine 001 is the backward direction, and this definition will be continued hereinafter. The driving member 006 is in the first position in fig. 5, and the driving member 006 is in the second position in fig. 2-4.

The front end of the driving handle 004 extends out of the most front end of the gun body 007, and in a standby state, the driving handle 004 can be driven to drive in the front-back direction by pushing and pulling the part of the driving handle 004 extending out of the gun body 007. When the driving handle 004 is pushed backwards, the rear end of the driving handle 004 pushes the driving member 006 to slide backwards, the driving member 006 triggers the loading assembly 003, the loading assembly 003 completes loading operation of the gyro 002a, and the driving member 006 is locked by the triggering assembly 005, at this moment, the gyro gun is in a loading state.

The driving handle 004 is pulled back forward and pushed backward again, at this time, the driving member 006 is locked at the triggering component 005, the driving handle 004 pushes the driving position of the driving member 006 to rotate and accelerate the gyro 002a, and at this time, the gyro gun is in an accelerating state.

Trigger assembly 005 is triggered under the acceleration rate state, and the top rifle gets into the transmission state, launches the rifle body 007 with top 002a on the driving piece 006 outside, and each part of top rifle after launching this top 002a resumes to standby state again automatically, waits for the next transmission operation.

Further, as shown in fig. 2-7, the driving handle 004 includes a handle housing 401 and a push rod 402 connected in the handle housing 401, the handle housing 401 is exposed outside the gun body 007 and is held by a player, the push rod 402 is located in the gun body 007 and is movable along the length direction of the gun body 007, the handle housing 401 drives the push rod 402 to move synchronously when being driven, and the push rod 402 is used for pushing the driving member 006 to slide towards the first position and driving the top 002a to rotate and accelerate.

Specifically, the handle housing 401 extends out of the foremost end of the gun body 007, the front end of the push rod 402 is fixed in the handle housing 401, and the rear end is located in the gun body 007. In a standby state, the handle housing 401 is driven to slide towards the first position, and the push rod 402 pushes the driving member 006 to trigger the loading assembly 003; in the loading state, the handle shell 401 of the driving handle 004 is driven to slide towards the first position, and the top 002a is driven to rotate and accelerate.

Referring to fig. 8, in the present embodiment, the push rod 402 includes a first push rod 421 and a second push rod 422 arranged side by side, the front ends of the first push rod 421 and the second push rod 422 are both connected in the handle housing 401, the rear ends of the first push rod and the second push rod 422 are both provided with push blocks 423 protruding upward, when the driving handle 004 is driven to slide towards the first position in the standby state, the two push blocks 423 simultaneously contact with the elastic protrusions 608 at the front end of the driving member 006, and push the driving member 006 to slide towards the magazine 001.

As shown in fig. 9, the driving member 006 includes an upper driving plate 606 and a lower driving plate 607, an elastic projection 608 is installed between the upper driving plate 606 and the lower driving plate 607 by a projection elastic member 609, and the elastic projection 608 protrudes two projections 681 below the lower driving plate 607, rear ends of the two projections 681 being provided with inclined surfaces.

In a standby state, the two push blocks 423 of the first push rod 421 and the second push rod 422 are located behind the two protrusions 681, when the magazine is loaded, the driving handle 004 is pushed towards the front end of the gun body 007, the push block 423 pushes the protrusions 681 to be retracted between the upper driving plate 606 and the lower driving plate 607, the push block 423 slides to the front end of the driving member 006, the driving handle 006 is pushed towards the rear end of the gun body 007, and the push block 423 pushes the front end of the protrusions 681 to further push the driving member 006 to slide towards the magazine 001. The first push rod 421 is further connected to a push rod elastic member 424, one end of the push rod elastic member 424 is connected to the gun body 007, and the other end is connected to the first push rod 421. The push rod elastic member 424 may be an extension spring or a compression spring. When the push rod elastic element 424 is an extension spring, the push rod elastic element 424 is extended to store energy when the driving handle 004 is pulled out forwards, and when the driving handle is released, the push rod elastic element 424 drives the driving handle 004 to return backwards. When the push rod elastic member 424 is a compression spring, the push rod elastic member 424 is compressed when the driving handle 004 is pushed backward, and when the driving handle 004 is released, the driving handle 004 can slide back to the foremost end of the gun body 007 under the elastic force of the push rod elastic member 242.

Further, as shown in fig. 2-8, the gyro gun further includes a gyro accelerator 403, the gyro accelerator 403 is fixed in the gun body 007, and the push rod 402 is matched with the gyro accelerator 403;

the driving member 006 includes a gyro seat 601 for placing the gyro 002, the gyro seat 601 is connected to the driving member 006 in a relatively rotatable manner, a rotating gear 612 is arranged at the lower end of the gyro seat 601 to be meshed with the gyro accelerator 403, and in an accelerating state, the push rod 402 drives the gyro accelerator 403 to continuously accelerate the gyro seat 601 and the gyro 002a on the gyro seat 601 in a rotating manner when reciprocating along the length direction of the gun body 007. Specifically, the gyro seat 601 provides a driving position for the driving member 006, and the gyro 002a is placed on the gyro seat 601 in the loading state.

As shown in fig. 8, the gyro accelerator 403 includes an accelerator housing 431, a gear set 432 and a rack 433, the gear set 432 is installed in the accelerator housing 431, the accelerator housing 431 is installed in the gun body 007, the gear set 432 is composed of a plurality of sets of coaxial reduction gears, and an opening is provided on a side of the accelerator housing 431 facing the driver 006. The rack 433 is connected at the rear end of the push rod 402 of the driving handle 004, specifically the rear end of the first push rod 421 in this embodiment, the rack 433 is arranged along the length direction of the gun body 007, the rack 433 and the first push rod 421 can be integrally formed, and the rack 433 is meshed with the gear set 432.

In the loading state, the rotating gear 612 is meshed with the gear set 432 from the opening of the accelerator housing 431, the rack 433 is meshed with the gear set 432, the gear set 432 is driven to rotate, and the gear set 432 drives the rotating gear 612 to further drive the gyro seat 601 and the gyro 002a thereon to rotate in an accelerating mode by utilizing the speed reduction principle of the gear. The structure of the gear set 432 is the same as that of a gear reducer or a gear accelerator in the prior art, and will not be described herein.

Further, as shown in fig. 8, the driving member 006 is installed in the gun body 007 through the driving elastic member 603, when the triggering member 005 locks the driving member 006, the driving elastic member 603 is charged with energy, and when the triggering member 005 unlocks the driving member 006, the driving elastic member 603 is discharged with energy, so that the driving member 006 is driven to slide from the first position to the second position.

Specifically, drive elastic component 603 one end is fixed in the front end of rifle body 007, and driving piece 006 is connected to one end, and when driving piece 006 was locked at the primary importance, drive elastic component 603 was elongated the energy storage, and when trigger component 005 unblock driving piece 006, drive elastic component 603 released the energy, drove driving piece 006 and slided towards the second place, launches top 002a on the top seat 601 of driving piece 006.

Further, as shown in fig. 8 and 10, the driving member 006 further includes a thimble 611, the thimble 611 is located at the bottom of the driving position and can move in the direction that the top 002 is disengaged from the driving member 006;

the front end of the gun body 007 is provided with a launching guide surface 711 which is gradually inclined upward in a direction in which the top 002a is ejected out of the gun body 007, and when the lower end of the driving member 006 slides to the launching guide surface 711, the ejector pin 611 is guided by the launching guide surface 711 to be ejected upward to push the top 002a out of the gun body 007.

The design of the thimble 611 and the launching guide surface 711 is to realize that the top 002 can jump out from the front end of the bore of the gun body 007, so that the visual effect of jumping and casting is achieved, and the launching safety is also improved. Certainly, under the prerequisite of not considering the visual effect of jump casting, also can save thimble 611 and transmission guiding surface 711, directly set up the jet outlet of top 002 at the front end opening part of bore, top 002 can directly break away from the back and jet out to the bore front end opening part from driving piece 006 under driving piece 006's drive like this.

Specifically, an opening is formed in the gyro base 601, and the diameter of the upper end of the thimble 611 is larger than that of the opening, so that the upper end of the thimble 611 cannot fall off from the opening, and the thimble 611 can slide up and down in the gyro base 601.

The gun body 007 is provided with a sloping block 701 between a driving piece 006 and a driving handle 004, a launching guide surface 711 is arranged on the sloping block 701, the frontmost end of the launching guide surface 711 is also provided with a launching plane 712, and the height of the launching plane 712 is the same as that of the frontmost end of the launching guide surface 711. When the lower end of the thimble 611 of the gyro base 601 slides onto the emission plane 712, the thimble 611 ejects the gyro 002 thereon above the gun body 007, and the gyro 002 keeps rotating under the inertia action and emits the gun body 007 towards the front end.

In this embodiment, a swash block mounting rod 702 is fixedly mounted in the barrel of the gun body 007, and the swash block mounting rod 702 is disposed along the length direction of the gun body 007, is located outside the second push rod 411 of the driving handle, and is disposed in parallel with the second push rod 411. The sloping block 701 is fixedly connected to a side of the sloping block mounting rod 702 close to the second push rod 411, and when the driving member 006 slides, the thimble 611 of the gyro base 601 slides between the sloping block mounting rod 702 and the second push rod 411, so as to guide the thimble 611.

Further, as shown in fig. 2-6, the loading assembly 003 is located between the magazine 001 and the driving member 006, the radial direction of the gyro 002 in the magazine 001 is perpendicular to the length direction of the gun body 007, and a plurality of gyros 002 are stacked in the magazine 001;

when the drive member 006 triggers the loading assembly 003, the loading assembly 003 picks the foremost gyro 002a in the magazine 001 to swing backward to the radial direction of the gyro 002a parallel to the length direction of the gun body 007, and the gyro 002a is placed on the drive position of the drive member 006.

Specifically, the radial direction of the gyro 002 in the magazine 001 is perpendicular to the length direction of the gun body 007, and a plurality of gyros 002 in the magazine 001 are stacked along the length of the gun body 007. When the loading assembly 003 is loaded, one spinning top 002a closest to the loading assembly 003 in the magazine 001 is grabbed, and then the spinning top 002a is swung to be parallel to the length direction of the gun body 007 in the radial direction, and the spinning top 002a keeps parallel to the length direction of the gun body 007 in the radial direction in the process of launching.

In the above arrangement of the present application, the direction of the top 002 in the magazine 001 is perpendicular to the direction of the top 002 when it is launched, which enables the axial direction of the magazine 001 to be arranged along the length direction of the gun body 007, so that the magazine can be designed to be longer and can store more tops therein. If the direction of the gyro 002 in the magazine 001 is kept the same as the direction of the gyro during shooting and the magazine 001 needs to be placed in the axial direction along the height direction of the gun body 007, the size of the gun body 007 needs to be increased and the structure of the gun body 007 needs to be changed, so that the difference between the appearance and the playing method of the gyro gun and the toy gun is large, and the playability of the gyro gun is reduced.

Further, the loading assembly 003 comprises a collar 311, a rotary pusher 312 and a collar energy storage member 313, wherein the rotary pusher 312 is mounted at the lower end of the collar 311, and the collar energy storage member 313 is connected between the collar 311 and the rotary pusher 312;

when the driving handle 004 is driven, the driving handle 004 drives the driving member 006 to push the rotary pushing member 312, the rotary pushing member 312 pushes the collar 311 to swing from a preparation position which is radially vertical to the length direction of the gun body 007 to a loading position which is radially parallel to the length direction of the gun body 007, and the collar energy storage member 313 stores energy;

the collar energy accumulator 313 drives the swinging of the collar 311 from the cocked position to the ready position upon release of energy.

Specifically, as shown in fig. 10, the collar 311 is driven by the driving member 006, when loading, the driving member 006 slides towards the collar 311 to push the rotating pushing member 312 connected to the lower end of the collar 311, the rotating pushing member 312 drives the collar 311 to swing, and the collar energy storage member 313 stores energy during the swinging process. When the driving member 006 pushes the ring 311 to the state shown in fig. 3, the top 002a grabbed by the ring 311 is exactly located at the designated position on the driving member 006 where the top is placed, at this time, the ring 311 releases the top 002a, the ring energy storage member 313 drives the ring 311 to swing back to the ready position, loading of the top 002a is completed, and the loaded top gun is in the state shown in fig. 4.

In this embodiment, the energy storage member 313 is a torsion spring, which can be replaced by an elastic member such as a spring.

Further, as shown in fig. 10, the lower end of the collar 311 is provided with a swing portion 3111, and the rotary push piece 312 is connected to the swing portion 3111 through the collar rotating shaft 314;

the lantern ring rotating shaft 314 penetrates through the swinging part 3111 and the rotating push piece 312, the rotating push piece 312 pushes the lantern ring 311 to rotate by taking the lantern ring rotating shaft 314 as an axis, the lantern ring energy storage piece 313 is sleeved and fixed outside the lantern ring rotating shaft 314, one end of the lantern ring energy storage piece is connected with the swinging part 3111, the other end of the lantern ring energy storage piece is connected with the rotating push piece 312, and the lantern ring energy storage piece is used for limiting an included angle between the swinging part 3111 and the rotating push piece 312 to be kept at.

Specifically, referring to fig. 11, the swing portion 3111 extends from the lower end of the collar 311 toward the driving member 006, and in this embodiment, the swing portion 3111 is provided as two ear plates disposed in parallel, and the ear plates are provided with through holes. The upper end of the rotary pushing member 312 is also provided with a through hole, and the lower end of the rotary pushing member extends downwards to form two pushing portions 3121 arranged side by side. The upper end of the rotating push piece 312 is inserted between two ear plates of the swing portion 3111, and the collar rotating shaft 314 passes through the swing portion 3111 and the rotating push piece 312 and then is connected with the inner wall of the shell of the gyro gun, so that the swing portion 3111 and the rotating push piece 312 can rotate by taking the collar rotating shaft 314 as an axis.

Wherein, a side surface of the rotary push member 312 close to the collar 311 is tightly attached to the swing portion 3111, and when the driving member 006 pushes the rotary push member 312 towards the collar 311, the rotary push member 312 simultaneously pushes the collar 311 to rotate.

The spring body of the lantern ring energy storage part 313 is sleeved outside the lantern ring rotating shaft 314 and is fixed with the lantern ring rotating shaft 314, one of two connecting ends extending out of two ends of the spring body is connected with the swinging part 3111, the other connecting end is connected with the rotating push part 312, and the lantern ring energy storage part 313 limits the positions among the lantern ring 311, the rotating push part 312 and the lantern ring rotating shaft 314. When the rotary push piece 312 and the lantern ring 311 rotate, the spring body 313 is compressed to store energy; when the external force pushing the rotary pushing piece 312 disappears, the lantern ring energy storage piece 313 releases energy to push the rotary pushing piece 312 and the lantern ring 314 to rotate back, and the lantern ring 311 and the rotary pushing piece 312 return to the preparation position.

In this embodiment, two energy storage members 313 are provided, and two energy storage members 313 are provided on two sides of the rotating pushing member 312, so that the swinging force of the collar 311 is balanced.

Further, as shown in fig. 10, a driving top block 604 is disposed on the driving member 006, and the driving top block 604 protrudes from the upper surface of the driving member 006 for pushing the rotary pushing member 312.

Specifically, the rotary push member 312 includes two push portions 3121 extending downward, and the two push portions 3121 are disposed side by side at both sides of the lower end of the rotary push member 312. Two driving ejector blocks 604 are correspondingly arranged, and the two driving ejector blocks 604 are respectively contacted with the two pushing portions 3121 to push the rotary push piece 312 to rotate. The two side-by-side pushing portions 3121 are provided, so that when the driving member 006 pushes the rotary pushing member 312, the force applied to the rotary pushing member 312 is uniform, and the swinging force of the collar 311 is balanced.

Further, as shown in fig. 2-5, the loading assembly 003 further includes collar guide slots 303, the collar guide slots 303 being located on either side of the collar 311;

guide protrusions 3112 extend outward from both sides of the collar 311, the guide protrusions 3112 are inserted into the collar guide grooves 303, and the guide protrusions 3112 move along the collar guide grooves 303 when the collar 311 is switched between the ready position and the loading position.

Specifically, the collar guide groove 303 is arc-shaped, and the collar guide groove 303 may be disposed on the inner wall of the housing of the gun body 007. The lantern ring 311 is provided with a lantern ring guide groove 303 on each side, and the two guide protrusions 3112 on each side of the lantern ring 311 are inserted into one lantern ring guide groove 303 to keep the stability of the lantern ring 311 in the swinging process.

Further, the lantern ring 311 is provided with a lantern ring locking piece 300 for locking the gyro 002 in the lantern ring 311, and when the lantern ring 311 swings to the parallel state shown in fig. 3, the lantern ring locking piece 300 unlocks the gyro 002, and the gyro 002 drops on the driving position of the driving piece 006.

Specifically, collar lock 300 includes an upper collar lock 304 and a lower collar lock 305 respectively mounted at the upper end and the lower end of collar 311, and the connection line of the two passes through the center of circle of collar 311, and is matched to lock top 002 in collar 311.

The upper lantern ring locking piece 304 has a part movably extending into the lantern ring 311 to shield the top 002 of the lantern ring 311, and when the upper lantern ring locking piece is unlocked, the part extending into the lantern ring 311 is moved out of the lantern ring 311.

Lower collar lock 305 is the same as upper collar lock 304, and part of it movably extends into collar 311 to shield top 002 of collar 311, and when unlocking, the part extending into collar 311 moves out of collar 311.

As the collar 311 swings to the uphole position, the upper collar lock 304 and the lower collar lock 305 are unlocked simultaneously.

Further, as shown in fig. 11, the upper collar lock 304 includes an upper lock housing 341, an upper front lock 342, and an upper rear lock 343, the upper front lock 342 and the upper rear lock 343 being telescopically mounted in the upper lock housing 341;

the upper front lock catch 342 is located on one side of the collar 311 facing the driving member 006, the upper front lock catch 342 extends into the collar 311 when locked, and the upper front lock catch 342 extends out of the upper lock member housing 341 when unlocked;

upper rear catch 343 is located on the side of collar 344 facing the magazine 001 and extends into collar 311, and during the process of top 002 entering collar 311 from magazine 001, upper rear catch 342 is pressed back into upper lock housing 341.

Specifically, the upper front latch 342 is installed in the upper latch housing 341 through an upper front elastic member 344, one end of the upper front elastic member 344 abuts against a middle section of the upper front latch 342, and the other end abuts against an outer surface of the collar 311. When the upper front elastic piece 344 is in a natural state, the upper front lock catch 342 is pushed to extend out of the upper lock piece housing 341; when the upper front resilient member 344 is compressed, the upper front catch 342 extends into the collar 311.

The upper rear locker 343 is installed in the upper locker housing 341 by an upper rear elastic member 345, and one end of the upper rear elastic member 345 abuts against the inner wall of the upper locker housing 341 and the other end abuts against the upper rear locker 343. Also, the side of the upper rear lock 343 facing the magazine 001 is provided with an inclined surface, and when the top 002 in the magazine 001 is pushed into the collar 311, the outer edge of the top 002 moves along the inclined surface, gradually pushing the upper rear lock 342 to retract into the upper lock housing 341.

The lower collar lock 305 is vertically symmetrical to the upper collar lock 304, the lower collar lock 305 includes a lower lock housing 351, a lower front lock 352 and a lower rear lock 353, and the lower front lock 352 and the lower rear lock 353 are telescopically mounted in the lower lock housing 351;

the lower front lock 352 is located on one side of the collar 311 facing the driving member 006, the lower front lock 352 extends into the collar 311 when locked, and the lower front lock 352 extends out of the lower lock housing 351 when unlocked;

lower rear lock 353 is located on the side of collar 311 facing the magazine 001 and extends into collar 311, and during the process of top 002 entering collar 311 from magazine 001, lower rear lock 353 is compressed and retracted into lower lock housing 351.

Specifically, the lower front latch 352 is mounted in the lower latch housing 351 through a lower front elastic member 354, one end of the lower front elastic member 354 abuts against a middle section of the lower front latch 352, and the other end abuts against an outer surface of the collar 311. When the lower front elastic member 354 is in a natural state, the lower front lock 352 is pushed to extend out of the lower lock housing 351; when the lower front resilient member 354 is compressed, the lower front catch 3542 extends into the collar 311.

The lower rear locker 353 is installed in the lower locker housing 351 by the lower rear elastic member 355, one end of the lower rear elastic member 355 abuts against the inner wall of the lower locker housing 351, and the other end abuts against the lower rear locker 353. Also, the side of the lower rear lock 353 facing the magazine 001 is provided with an inclined surface, and when the top 002 in the magazine 001 is pushed into the collar 311, the outer edge of the top 002 moves along the inclined surface, gradually pushing the lower rear lock 352 to retract into the lower lock housing 351.

The lower collar lock 305 differs from the upper collar lock 304 in that the lower lock housing 351 also extends beyond a support hook 3511 on the side facing the driver 006. The upper end of the aforementioned rotating push piece 312 is provided with a rotating shaft connecting portion 3122 for passing through the collar rotating shaft 314, a through hole 3123 is formed at the lower end of the rotating shaft 3122, and two push portions 3121 extend downward from both sides of the through hole 3123. The support hook 3511 penetrates through the through hole 3123, such that the rotation shaft connecting portion 3122 is mounted on the support hook 3511, and the support hook 3511 provides support for the rotation push piece 312. When the rotary pushing element 312 rotates, the supporting hook 3511 is pushed to drive the lower collar lock 305 to rotate synchronously.

Further, as shown in fig. 12 and 13, the cocking assembly 003 further includes an upper latch guide slot 306, the upper latch guide slot 306 being located above the upper collar latch 304;

when the collar 311 is in the ready position shown in fig. 12, the inner wall of the upper lock guide groove 306 is tightly attached to the upper surface of the upper lock housing 341, the upper front lock catch 342 is pressed to extend into the collar 311 until the collar 311 swings to the loading position shown in fig. 13, and when the upper surface of the upper lock housing 341 is separated from the upper lock guide groove 306, the upper front lock catch 342 extends out of the upper surface of the upper lock housing 341, so as to unlock the top 002;

when the lantern ring 311 is in the ready position, the lower surface of the lower lock housing 351 is tightly attached to the upper surface of the driving member 006, the lower front lock 352 is pressed to extend into the lantern ring 311 until the lantern ring 311 swings to the upper chamber position, and when the lower surface of the lower lock housing 351 is separated from the upper surface of the driving member 006, the lower front lock 352 extends out of the lower surface of the lower lock housing 351, and the top 002 is unlocked.

Specifically, the upper locking piece guide groove 306 is arranged on the inner wall of the outer shell of the gun body 007, the upper locking piece guide groove 306 is arc-shaped, the upper surface of the upper locking piece outer shell 341 keeps clinging to the inner wall of the upper locking piece guide groove 306 in the preparation position and the swinging process of the lantern ring 311, the upper front lock catch 342 is continuously extruded, and the upper front lock catch 342 extends into the lantern ring 311 to lock the top 002. When the ring 311 is swung to the loading position shown in fig. 13, the upper lock housing 341 is disengaged from the upper lock guide groove 306, and the upper front lock catch 342 is not pressed any more, and then protrudes out of the upper surface of the upper lock housing 341 of the top, so as to unlock the top 002.

For the lower collar lock 305, during the preparation position and swing of the collar 311, the lower surface of the lower lock housing 351 is tightly attached to the upper surface of the driving member 006, and the lower front lock 352 is continuously pressed, so that the lower front lock 352 extends into the collar 311 to lock the top 002. When the collar 311 is swung to the cocked position shown in fig. 13, the lower surface of the lower collar lock 305 is perpendicular to the upper surface of the driving member 006, and the lower front lock 352 does not protrude beyond the lower surface of the top lower lock housing 351 without being pressed by the upper surface of the driving member 006, thereby unlocking the top 002.

Further, as shown in fig. 2-6 and 10, the loading assembly 003 further comprises a top stopper 307, the top stopper 307 is rotatably mounted between the collar 311 and the magazine 001;

the drive knob 004 pushes a portion of the top stop 307 to be trapped between the collar 311 and the magazine 001 as the drive member 006 is driven to slide toward the collar 311.

Specifically, before the loading operation is performed, the driving member 006 is farthest from the collar 311, and the top 002 in the magazine 001 is not shielded, and the top 002 in the magazine 001 presses the collar 311 forward, and the foremost one of the tops 002 enters the collar 311.

When the loading operation is performed, as the driving member 006 slides towards the collar 311, the driving member 006 pushes the top stopper 307 to partially shield between the collar 311 and the magazine 001, so as to limit the top 002 in the magazine 001 to be ejected out of the magazine 001.

Further, as shown in fig. 10, the top stopper 307 includes an upper stopper 371, a lower swing 372, a stopper rotating shaft 373, and a stopper twisting member 374;

the upper stop portion 371 and the lower swing portion 372 are integrally formed, the stopper rotating shaft 373 penetrates through the connection position of the upper stop portion 371 and the lower swing portion 372, and the stopper twisting member 374 is sleeved on the stopper rotating shaft 373;

when the driving member 006 slides towards the collar 311, the side edge of the driving member 006 pushes the skirt portion 372 to rotate outwards, so that the upper stop portion 371 is shielded between the collar 311 and the magazine 001, and the stop member twisting member 374 is charged with energy;

when the driving member 006 slides away from the collar 311, the catch torsion member 374 releases energy to drive the skirt portion 372 to rotate inward, and the upper stop portion 371 rotates to the outside of the collar 311 and the magazine 001.

Specifically, the catch torsion 374 is energized before the up-stop 371 is positioned outside the collar 311 and the down-swing 372 is positioned below the collar 311. When the driving member 006 is slid toward the collar 311, the side of the driving member 006 pushes the skirt portion 372 outward, the upper stop portion 371 and the skirt portion 372 rotate around the stop rotating shaft 373, so that the upper stop portion 371 rotates inward to block between the collar 311 and the magazine 001, and the stop torsion member 374 stores energy.

When the driving member 006 drives the top 002 thereon to be emitted along the length direction of the gun body 007, the side edge of the driving member 006 no longer pushes the lower swing part 372, the stopping part torsion part 374 releases energy, the upper stopping part 371 turns to the outer side of the lantern ring 311, the upper stopping part is no longer shielded between the lantern ring 311 and the magazine 001, the top elastic part 104 pushes the next top 002 to enter the lantern ring 311, and the lantern ring 311 grabs the top 002.

As shown in fig. 10, in this embodiment, two sides of the collar 311 are respectively provided with a top stopper 307, which are respectively pushed by two sides of the driving member 006.

Further, as shown in fig. 2-6 and 10, the loading assembly 003 further includes a rotatable collar front lock 308, the collar front lock 308 is partially shielded on a side of the collar 311 facing the driver 006 for locking the collar 311, and the driver 006 slides towards the collar 311 to push the collar front lock 308 to rotate outwards to unlock the collar 311.

Specifically, the collar front lock 308 is used to lock the collar 311, so as to prevent the collar 311 from moving along the collar guide groove 303 under other external forces when the loading operation is not performed, for example, when the external force impacts a large amount, such as swinging a gyro gun, and falling the gyro gun.

Further, as shown in fig. 14 and 15, the collar front lock 308 includes a vertical rotation member 381, a lateral rotation member 382, and a front lock stopper 383, the lateral rotation member 382 being located between the vertical rotation member 381 and the front lock stopper 383;

the front lock stopper 383 covers one side of the lantern ring 311 facing the driving piece 006, and when the driving piece 006 pushes the vertical rotating piece 381 to rotate, the vertical rotating piece 381 drives the transverse rotating piece 382 and the front lock stopper 383 to rotate towards the outside of the lantern ring 311, so that the lantern ring 311 is unlocked.

Specifically, the lantern ring front lock 308 further comprises a vertical rotating shaft 384 and a transverse rotating shaft 385 which are installed in the gun body 007, the vertical rotating shaft 384 penetrates through the vertical rotating member 381, and the vertical rotating member 381 can rotate around the vertical rotating shaft 384; the transverse rotating shaft 385 penetrates into the transverse rotating member 382, and the transverse rotating member 382 can rotate around the transverse rotating shaft 385; and the vertical rotation shaft 384 and the lateral rotation shaft 385 are perpendicular to each other.

The vertical rotating shaft 384 is further sleeved with a front lock torsion member 386, and the outer side of the front lock torsion member 383 is connected with the inner wall of the shell of the gyro gun through a front lock energy storage member 387.

When the front lock push plate 605 pushes the vertical rotating member 381, the vertical rotating member 381 rotates around the vertical rotating shaft 384, the front lock twisting member 386 stores energy, the vertical rotating member 381 pushes the transverse rotating member 382 to rotate around the transverse rotating shaft 385, the transverse rotating member 382 pushes the front lock stopper 383 to compress the front lock energy storage member 387, and the front lock stopper 383 moves towards the outer side of the collar 311 along the radial direction of the collar 311 to unlock the collar 311;

until the driving member 006 drives the gyro 002 thereon to be launched out along the length direction of the gun body 007, the front lock push plate 605 no longer pushes the vertical rotating member 381, the front lock twisting member 386 releases energy, the vertical rotating member 381 rotates, the transverse rotating member 382 and the front lock stopping member 383 are no longer extruded, the front lock energy storage member 387 releases energy, and the front lock stopping member 383 is pushed to shield one side of the lantern ring 311 close to the driving member 006.

In this embodiment, two sets of the transverse rotating member 382 and the transverse rotating shaft 385 are provided. Specifically, two transverse rotating members 382 are arranged in the vertical direction, the upper transverse rotating member 382 is directly connected to the front stopper 383, and the lower transverse rotating member 382 is directly connected to the vertical rotating member 381. After the vertical rotating member 381 pushes the lower transverse rotating member 382, the lower transverse rotating member 382 pushes the upper transverse rotating member 382 to rotate, and the upper transverse rotating member 382 pushes the front lock 383 to compress the front lock energy storage member 387.

Further, as shown in fig. 2-8, trigger assembly 005 includes a cooperating trigger 501 and an actuating lock rod 502;

when the driving handle 004 is driven, the driving handle 004 pushes the driving member 006 to slide to the position of the driving lock rod 502, and the driving lock rod 502 locks the driving member 006;

when trigger 501 is triggered, trigger 501 pushes drive lock lever 502 to unlock drive member 006.

Wherein, the driving lock rod 502 is used for locking the driving piece 006, and the trigger 501 is used for triggering the driving piece 006 to unlock, simulating the shooting method of the toy gun.

Alternatively, the trigger 501 may be arranged to lock the drive member 005 directly, if the construction permits.

Further, as shown in fig. 8, both the trigger 501 and the driving lock lever 502 are telescopically mounted in the gun body 007, the trigger 501 is telescopic in the length direction of the gun body 007, and the driving lock lever 502 is telescopic in the height direction of the gun body 007;

a locking groove (not shown) is formed in the lower surface of the driving member 006, and when the driving member 006 slides above the driving locking bar 502, the upper end of the driving locking bar 502 is pushed downwards to enter the locking groove, and then the driving locking bar 502 springs up to lock the driving member 006;

when the trigger 501 is pushed, the trigger 501 drives the driving lock rod 502 downward, and the driving lock rod 502 unlocks the driving member 006.

Specifically, the driving lock lever 502 is coupled to the gun body 007 through the lock lever elastic member 503, and the trigger 501 is coupled to the front side of the driving lock lever 501 through the trigger elastic member 504. An inclined lock rod guide surface 521 is arranged in the driving lock rod 502, an inclined trigger guide surface 511 is correspondingly arranged in the trigger 501, the lock rod guide surface 521 is gradually inclined downwards from back to front, and the inclination angle of the trigger guide surface 511 is the same as that of the lock rod guide surface 521. When the trigger 501 moves backward, the trigger guide surface 511 moves against the lock rod guide surface 521, and the driving lock rod 502 is pushed to compress the lock rod elastic member 503 to move downward, so that the upper end of the driving rod 502 is separated from the locking groove, and the driving member 006 is unlocked.

Further, as shown in fig. 16, the magazine 001 includes a magazine barrel 101 for housing at least two spinning tops 002 and a spinning top lock and an elastic pusher 103 installed in the magazine barrel 101;

an elastic pushing member 103 is installed in the magazine barrel 101 and used for pushing the spinning top 002 to the opening position of the magazine barrel 101;

the gyro lock 102 is located at an opening position of the magazine barrel 101, and the gyro lock 102 is used for locking the gyro 002 in the magazine barrel 101;

when the top lock 102 is triggered, the top 002 is unlocked, and the elastic pushing piece 103 pushes the top 002 at the most front end out of the magazine barrel 101.

Specifically, the magazine barrel 101 is in a long strip shape, the opening is disposed at one end of the magazine barrel 101 in the length direction, and the elastic pushing member 103 has a tendency to move toward the opening. When the gyro lock 102 is not triggered, part of the gyro lock 102 is shielded at the opening position of the magazine barrel 101 to limit the gyro 002 in the magazine barrel 101 to be pushed out of the opening, when the gyro lock 102 is triggered, the part of the gyro lock 102 shielded at the opening position of the magazine barrel 101 is far away from the opening position, and the gyro 002 in the magazine barrel 101 is not blocked any more and is pushed out of the magazine barrel 101 under the action of the elastic pushing piece 103.

The magazine case 101 can continuously house a plurality of spinning tops 002, the plurality of spinning tops 002 are stacked on the side of the elastic push piece 103 facing the opening, and the elastic push piece 103 is pressed toward the bottom of the magazine case 101 as the number of spinning tops 002 housed in the magazine case 101 increases.

When the magazine 001 is loaded into the gun body 007, the gun body 007 triggers the gyro lock 102, the gyros 002 in the magazine case 101 are unlocked, and are sequentially pushed out of the magazine case 101 by the elastic push piece 103.

Further, the top lock 102 comprises a locking buckle 121 and a striking piece 122, a part of the locking buckle 121 movably extends into the magazine barrel 101 for locking the top 002 in the magazine barrel 101, and the striking piece 122 is in linkage fit with the locking buckle 121 and partially extends out of the magazine barrel 101;

when the striker 122 is triggered, the locking buckle 121 releases the locking of the top 002, and the elastic pusher 103 pushes the top 002 out of the opening of the magazine barrel 101.

Specifically, when the striking member 122 is not triggered, the locking buckle 121 of the gyroscope lock 102 partially extends into the magazine barrel 101 to be shielded at the opening position, and when the striking member 122 is triggered or the locking buckle 121 is pushed, the locking buckle 121 moves outward of the magazine barrel 101 to no longer shield the opening position of the magazine barrel 101.

The top 002 is loaded from the opening of the magazine barrel 101, the locking buckle 121 shielded at the opening position is pushed to enter the magazine barrel 101, the elastic pushing piece 103 is pushed towards the interior of the magazine barrel 101, the elastic pushing piece 103 continuously applies pushing force to the top 002 outwards from the opening, the locking buckle 121 is restored to the state shielded at the opening position of the magazine barrel 101 because the top 002 does not push the locking buckle 121 after entering the magazine barrel 101, and the top 002 is locked in the magazine barrel 101.

Further, as shown in fig. 17 and 18, the magazine 001 further includes a gyro elastic member 104, the magazine barrel 101 is cylindrical, one end of the magazine barrel 101 in the axial direction is provided with an opening, the other end of the magazine barrel is provided with a bottom plate 111, the elastic pushing member 103 is connected to the bottom plate 111 through the gyro elastic member 104, and the gyro elastic member 104 is configured to push the elastic pushing member 103 toward the opening in the axial direction of the magazine barrel 101.

Specifically, the top elastic member 104 is disposed along the axial direction of the magazine barrel 101, one end is connected to the bottom plate 111, the other end is connected to the elastic pushing member 103, and the natural length of the top elastic member 104 is greater than or equal to the length of the magazine barrel 101, and when the top 002 is locked in the magazine barrel 101, the top elastic member 104 is compressed, so that the elastic pushing member 103 tends to move toward the opening in the magazine barrel 101.

Since the top 002 is generally provided in a circular shape, the magazine case 101 in this embodiment is provided in a cylindrical shape, and correspondingly, the outer edge of the elastic pusher 103 is also provided in a circular shape so that it moves in the magazine case 101. Moreover, the inner wall of the magazine barrel 101 may further be provided with a guide rail, and the outer edge of the elastic pushing member 103 is correspondingly provided with a notch or a protrusion matched with the guide rail to guide the movement of the elastic pushing member 103 in the magazine barrel 101.

Alternatively, the shape of the magazine barrel 101 may be provided as a correspondingly shaped cylinder according to the shape of the top 002.

Further, as shown in fig. 16-18, the elastic pushing element 103 includes a pushing plate 131 and a pushing column 132, the top elastic element 104 is connected to a surface of the pushing plate 131 facing the bottom plate 111, a raised boss 1311 is provided on a surface facing the opening, a cavity 1312 is provided inside the boss 1311, one end of the pushing column 132 is installed in the cavity 1312 through the pushing column elastic element 133, the other end of the pushing column 132 extends out from the boss 1311, the pushing column 132 is pressed when the top 002 is installed above the pushing plate 131, and at least two inverted tops 002 are axially overlapped on the pushing column 132.

Specifically, the push plate 131 and the boss 1311 are integrally formed, the boss 1311 is located at the center of the push plate 131, the center of the boss 1311 is provided with an opening of the cavity 1312, and the push rod 132 extends out of the opening. The diameter of the end of the push post 132 that is located in the cavity 1312 is larger than the diameter of the end that protrudes above the boss 1311, and the push post 132 will not fall out of the opening of the cavity 1312 at the edge of the opening of the cavity 1312.

One end of the push rod 132 located in the cavity 1312 is connected to a push rod elastic member 133, the push rod elastic member 133 is disposed along the axial direction of the magazine barrel 101, one end of the push rod elastic member 133 is connected to one end of the push rod 132, and the other end of the push rod elastic member abuts against the bottom of the cavity 1312. When the gyroscope 002 is loaded, the gyroscope 002 is inverted and then the push plate 131 is loaded, the protruding direction of the tip end of the gyroscope 002 is placed along the extending direction of the push column 132, the gyroscope 002 pushes the push column 132 to compress the push column elastic piece 133, when the last gyroscope 002 on the push plate 131 is launched, the push column elastic piece 133 bounces up to apply a pushing force to the gyroscope 002 to assist the gyroscope 002 to be pushed out, so that the defect that the pushing force of the gyroscope elastic piece 104 is small is overcome, and the last gyroscope 002 can be smoothly pushed out.

Further, as shown in fig. 18, the outer edge of the push plate 131 is provided with a front retainer 1313 and a rear retainer 1314;

the front retainer ring 1313 protrudes towards one side of the opening and is used for limiting the gyro 002 arranged on the push plate 131;

rear retainer 1314 protrudes toward one side of bottom plate 111 to limit top spring 104.

Specifically, in the magazine barrel 101, the front retainer 1313, the rear retainer 1314 and the push plate 131 are integrally formed, and the front retainer 313 and the rear retainer 314 form an annular connection to the outer edge of the push plate 131.

When the gyroscope 002 is arranged above the push plate 131, the front retainer 1313 shields the edge of the gyroscope 002 to prevent the position of the gyroscope 002 from shifting; the top elastic member 104 is connected to the inner wall of the rear retaining ring 1314, and under the shielding of the rear retaining ring 1314, the pushing force applied by the top elastic member 104 to the push plate 131 is kept along the axial direction of the magazine barrel 101.

Further, as shown in fig. 3 and 4, a mounting column 112 is disposed on the bottom plate 111 of the magazine barrel 101, a mounting groove 1121 is disposed on a surface of the mounting column 112 facing the opening, and one end of the top elastic member 104 is located in the mounting groove 1121.

Specifically, the mounting posts 112 provide mounting grooves 1121 for mounting the top spring 104, limit the position of the end of the top spring 104, prevent the top spring 104 from shaking, and stabilize the thrust of the top spring 104.

Further, the diameter of the top spring 104 gradually increases in the direction from the bottom plate 111 to the opening of the top spring 104.

Specifically, the diameter of one end of the top elastic member 104 connected to the push plate 131 is slightly smaller than the diameter of the push plate 131, so that the thrust applied to the push plate 131 by the top elastic member 104 is kept stable; the diameter of the end of the top spring 104 connected to the bottom plate is smaller than the diameter of the push plate 131, so as to reduce the space occupied by the top spring 104 in the magazine case 101 and make room for the arrangement of peripheral parts.

Further, as shown in fig. 16 and 18, two gyro locks 102 are disposed on the opening of the magazine barrel 101, and the two gyro locks 102 are disposed opposite to each other, and a line connecting the two gyro locks passes through the axis of the magazine barrel 101.

Optionally, three or more than three top locks 102 may be further disposed on the magazine barrel 101, and a plurality of top locks 102 are disposed at regular intervals on the opening of the magazine barrel 101.

As shown in fig. 5 and 6, the top lock 102 further includes a top lock housing 123 mounted outside the magazine barrel 101;

the locking buckle 121 is installed in the top lock housing 123 through a locking elastic member 124, the locking buckle 121 is telescopic in the radial direction of the magazine barrel 101, the striking member 122 is installed in the top lock housing 123 through a triggering elastic member 125, and the striking member 122 is telescopic in the axial direction of the magazine barrel 101;

the locking catch 121 and the striker 122 cooperate to bring the locking catch 121 into retraction towards the top lock housing 123 when the striker 122 is compressed into the top lock housing 123.

Specifically, the top lock housing 123 is mounted on the outer wall of the magazine barrel 101, and when the top lock housing is not interfered by an external force, the striking member 122 protrudes outward toward the opening along the axial direction of the magazine barrel 101, and the locking buckle 121 protrudes inward toward the magazine barrel 101. When the striking member 122 is pressed toward the magazine barrel 101, the locking buckle 121 is driven to retract into the top lock housing 123; when the striker 122 is not pressed, the lock catch 121 is pushed outward from the inside of the magazine case 101, and the lock catch 121 can be pushed into the top lock case 123.

Further, a through cavity 1221 is arranged in the striker 122, and two side walls of the through cavity 1221 are provided with inclined latch guide surfaces 1222;

the locking buckle 121 has locking guide 1211 protruding from both sides, the locking buckle 121 and the locking elastic member 124 are inserted into the through cavity 1221, and the locking guide 1211 is engaged with the locking guide 1222, so that when the striker 122 is compressed, the locking guide 1211 moves along the locking guide 1222 to retract the locking buckle 121 into the top lock housing 123.

As shown in fig. 19 and 20, the through cavity 1221 of the striker 122 penetrates in the radial direction of the magazine barrel 101, the locking buckle 121 is inserted into the through cavity 1221 from one side of the top lock housing 123, one end of the locking elastic member 124 abuts against the locking buckle 121, and the other end abuts against the inner wall of the top lock housing 123; the latch guide 1211 is engaged with the latch guide surface 1222 formed through the sidewall of the cavity 1221 to prevent the latch 121 from being separated from the cavity 1221, and to achieve the interlocking engagement of the latch 121 and the striker 122.

When the striking member 122 is pressed into the top lock housing 123, the lock guide surface 1222 moves into the top lock housing 123, and the lock guide 1211 of the lock catch 121 moves along the lock guide surface 1222, so that the lock catch 121 compresses the lock catch elastic member 124 and retracts into the top lock housing 123.

The locking button 121 is provided to be inclined toward one surface of the magazine case 101, and is inclined from the outside of the magazine case 101 toward the inside of the magazine case 101 toward the bottom end of the magazine case 101 from the front to the rear, and when the top 002 is loaded into the magazine case 101, the top 002 pushes the locking button 121 along the inclined surface to be retracted into the top lock case 123.

Further, as shown in fig. 18 and 21, the bottom end of the magazine barrel 101 is further provided with an elastic limiting block 113, a limiting elastic member 114, an unlocking button 114 and a button elastic member 116;

the elastic limiting block 113 is telescopically mounted in the magazine cylinder 101 through a limiting elastic member 114, and a part of the elastic limiting block extends out of the magazine cylinder 101 (see fig. 16 and 17) for limiting the position of the magazine 001 on the gun body 007;

the unlocking button 115 is telescopically mounted in the magazine barrel 101 through a button elastic member 116, and the unlocking button 115 is in linkage fit with the elastic stopper 113, and when the unlocking button 115 is pressed, the elastic stopper 113 is pushed to retract into the magazine barrel 101.

Specifically, as shown in fig. 16, when no external force is applied, the outer surface of the unlocking button 115 is flush with the outer surface of the magazine cylinder 101, the elastic limiting block 113 partially protrudes out of the outer surface of the magazine cylinder 101, and when the magazine 001 is mounted on the gun body 007, the protruding portion of the elastic limiting block 113 is embedded in the gun body 007, so that the magazine 001 is prevented from being detached from the gun body 007. When the magazine 001 is removed, the elastic stopper 113 is integrally retracted into the magazine barrel 101 by pressing the unlock button 115, so that the magazine 001 is separated from the gun body 007.

Further, as shown in fig. 21, there are two unlocking buttons 115, and the two unlocking buttons are symmetrically disposed on two sides of the elastic limiting block 113;

two inclined limiting guide surfaces 1131 are symmetrically arranged on two sides of the elastic limiting block 113, each unlocking button 115 is provided with one limiting guide column 1151, each limiting guide column 1151 is matched with one limiting guide surface 1131, and when the two unlocking buttons 115 are pressed simultaneously, the two limiting guide columns 1151 move along the limiting guide surfaces 1131 matched with the two limiting guide columns 1151 to push the elastic limiting block 113 to retract into the magazine barrel 101.

Specifically, the two limiting guide surfaces 1131 are arranged at one end of the elastic limiting block 113, which is located in the magazine cylinder 101, and a tip protruding out of the magazine cylinder 101 is formed between the two limiting guide surfaces 1131; one end of the limiting elastic part 114 is connected with one end of the elastic limiting block 113 in the magazine barrel 101, and the other end is connected with the outer wall of the mounting column 112.

The two unlocking keys 115 are oppositely arranged, one end of the key elastic piece 116 is connected with the inner side of the unlocking key 115, and the other end is connected with the outer wall of the mounting column 112; the limiting guide posts 1151 extend towards the elastic limiting block 113, when no external force is applied, the limiting guide posts 1151 are located at the outer edges of the limiting guide surfaces 1131 on the corresponding sides, when the two unlocking keys 115 are pressed simultaneously, the two limiting guide posts 1151 move along the corresponding limiting guide surfaces 1131, and the two limiting guide posts push the elastic limiting block 113 to retract into the magazine cylinder 101 together.

Referring to fig. 18 and 21, the magazine case 101 is formed of a left case 1011 and a right case 1012 which are fitted to each other to form the cylindrical magazine case 101. A partition plate 118 is further arranged above the bottom plate 111 of the magazine barrel 101, and a cavity for accommodating the mounting column 112, the elastic limiting block 113 and the unlocking key 115 is formed between the bottom plate 111 and the partition plate 117. The elastic limiting block 113 and the two unlocking keys 115 in the cavity are located on the outer side of the mounting column 112, wherein the two unlocking keys 115 are oppositely arranged on two sides of the mounting column 112, the elastic limiting block 113 is arranged between the two unlocking keys 115, the mounting column 112 extends outwards to form a supporting portion 1122 relative to the position of the elastic limiting block 113, the supporting portion 1122 is supported inside the magazine barrel 101, and the supporting portion 1122, the elastic limiting block 113 and the two unlocking keys 115 limit the mounting column 112 from four directions, so that the mounting column is fixed in the magazine barrel 101.

Further, as shown in fig. 16, the magazine barrel 101 is provided with a raised magazine slide rail 117 externally, and the magazine slide rail 117 is provided along the axial direction of the magazine barrel 101.

In particular, the magazine sliding track 117 is raised on the outer wall of the magazine barrel 101, which positions and guides the magazine 001 when it is inserted into the gyroscopic gun.

Alternatively, the magazine slide rail 117 may be provided as a concave rail.

The following is a detailed description of the operation of the gyro gun of the present embodiment:

before use, the gyro gun is loaded, the gyro 002 is loaded from the opening of the magazine barrel 101, the gyro 002 presses the gyro elastic member 104 into the magazine barrel 101 and then is locked in the magazine barrel 101 by the gyro lock 102, and a plurality of gyros 002 are sequentially loaded into the magazine 001.

And then simultaneously pressing the two unlocking pressing pieces 115 of the magazine barrel 101 to install the magazine 001 at the rear end of the gun body 001, and releasing the unlocking pressing pieces 115 after adjusting the position, so that the limiting elastic piece 114 is clamped in the gun body 007 to limit the magazine 001. When the magazine 001 is mounted on the gun body 007, the case of the gun body 007 strikes the striking piece 122 of the gyro lock 102, unlocking the gyro 002 in the magazine barrel 101. The foremost top 002a in the magazine barrel 101 is pushed out into the collar 311 of the upper bore assembly 003 and locked in the collar 311 by the upper collar lock 304 and the lower collar lock 305. The gyro gun is in a standby state at this time.

Then, the loading operation is performed, the driving handle 004 is pulled out from the front end of the gun body 007 and then pushed towards the rear end, the push rod 402 of the driving handle 004 pushes the driving member 006 to slide from the first position to the second position, and during the sliding process of the driving member 006, firstly, the front lock push plate 605 of the driving member 006 pushes the collar unlocking 308 to unlock the collar 311; then the side of the driving member 006 pushes the two top stoppers 307 to shield between the ring 311 and the magazine 001, so as to prevent the top 002b in the magazine 001 from being pushed out of the magazine 001; finally, the driving top block 604 of the driving member 006 pushes the rotary pushing member 312 at the lower end of the collar 311, and the driving collar 311 swings to the loading position as shown in fig. 3, which is radially parallel to the length direction of the gun body 007. At this time, the upper collar lock 304 and the lower collar lock 305 simultaneously unlock the gyro 002a, and the gyro 002a drops on the gyro seat 601 of the driving member 006.

The driving handle 004 is pushed to push the driving member 006 backwards continuously until the driving lock rod 502 locks the driving member 006, at this time, the driving top block 604 on the driving member 006 slides to the rear of the rotary pushing member 312, and the lantern ring 311 and the rotary pushing member 312 swing back to the preparation position which is perpendicular to the length direction of the gun body 007 in the radial direction under the action of the lantern ring energy storage member 313; moreover, the thimble 611 of the gyro base 601 is engaged with the gear set 432 in the gyro accelerator 403, and the gyro gun is in the loaded state as shown in fig. 4.

At this time, the driving handle 004 is pushed and pulled again, so that the rack 433 pushes the gear set 432 to rotate, the gear set 432 transmits the rotating force to the rotating gear 612, and the gyro base 601 and the gyro 002a thereon rotate at a high speed. The driving handle 004 can be repeatedly pushed for a plurality of times to keep the gyro 002a rotating and make the gyro gun in an accelerating state.

Under the state that the top 002a keeps rotating at a high speed, the trigger 501 is compressed backwards, the driving lock rod 502 unlocks the driving piece 006, and the driving piece 006 drives the top 002a on the driving piece 006 to slide towards the front end of the gun body 007 under the pulling force of the driving elastic piece 603. In the sliding process, when the lower end of the thimble 611 of the gyro base 601 slides onto the emission guide surface 711, the gyro 002a is gradually pushed out of the gun body 007 upwards until the lower end of the thimble 611 slides onto the emission plane 712, and the gyro 002a is emitted out of the gun body 007.

In the process of sliding the driving member 006 forward, the top block 604 is first driven to push the rotating push member 312 under the collar 311 forward from the back, the rotating push member 312 is pushed forward, the collar energy storage member 313 is compressed, and when the driving top block 604 slides to the front of the rotating push member 312, the collar energy storage member 313 pushes the rotating push member 312 to rotate to the lower end of the collar 311. Then, the side of the driving member 006 is separated from the top stopper 307, so that the top stopper 307 is no longer hidden between the magazine 001 and the collar 311, and the top elastic member 104 in the magazine 001 pushes the top 002b at the foremost end of the magazine 001 into the collar 311, as shown in fig. 5. Finally the front lock push plate 605 of the driver 006 disengages the collar front lock 308 and the collar front lock 308 locks the collar 311 again. Therefore, after the spinning top 002a is ejected out of the gun body 007, the spinning top gun returns to the standby state to wait for the next ejecting operation.

The gyro gun in this embodiment can be loaded with a plurality of gyros 002, and by operating the driving handle 004 to load and accelerate the gyros 002, the trigger 501 is pulled to launch the gyros 002, so that the gyros are loaded and launched in the form of bullets, and the gyros 002 can be continuously launched until all the gyros 002 in the magazine 001 are launched.

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

Claims (15)

1. A spinning top gun comprising a gun body (007) and a magazine (001) detachably mounted to said gun body (007), said magazine (001) being adapted to house at least two spinning tops (002);

the gun body (007) comprises a driving handle (004), a triggering assembly (005) and a driving position, one spinning top (002) in the magazine (001) can fall into the driving position through the driving handle (004), the spinning top (002) in the driving position can be subjected to rotating acceleration, and finally the spinning top (002) is ejected out of the gun body (007) through triggering the triggering assembly (005).

2. The spinning gun according to claim 1, characterized in that the gun body (007) further comprises a loading assembly (003) and a driving member (006) for placing and driving the spinning top (002) to fire, wherein the loading assembly (003) and the driving member (006) are in linkage fit with the driving handle (004), and the driving position is located on the driving member (006); when the driving handle (004) is driven,

firstly triggering the loading assembly (003) to grab one gyro (002) in the magazine (001) to be placed on the driving position of the driving piece (006);

then the driving piece (006) is driven to drive the gyro (002) on the driving position to rotate and accelerate.

3. The spinning gun according to claim 2, characterized in that said triggering assembly (005) is used to lock and trigger said driving member (006);

-when one of the gyros (002) in the magazine (001) falls into the drive position, the trigger assembly (005) locks the drive member (006);

when the trigger component (005) is triggered, the driving piece (006) is unlocked to emit the spinning top (002).

4. The gyroscopic gun according to claim 2, in which the driving member (006) is reciprocally slidable under the drive of the drive handle (004) between a first position close to the magazine (001) and a second position remote from the magazine (001), and the gyroscopic gun is in different states when the driving member (006) and the drive handle (004) are in different positions and actions, in which,

standby state: the spinning top gun is in a standby state when the driving piece (006) is at the second position;

loading state: when the driving handle (004) is driven to slide towards the first position for the first time, the driving handle (004) pushes the driving piece (006) to slide towards the upper chamber assembly (003) and triggers the upper chamber assembly (003), meanwhile, the driving piece (006) is locked at the first position, and then the driving handle (004) slides towards the second position;

an acceleration state: when the driving handle (004) is driven to slide towards the first position again, the driving handle (004) drives the spinning top (002) on the driving piece (006) to rotate and accelerate;

and (3) a transmitting state: when the trigger assembly (005) is triggered, unlocking the driving member (006) to slide to the second position and eject the spinning top (002).

5. The gyroscope gun as claimed in claim 4, wherein the driving handle (004) comprises a handle housing (401) and a push rod (402) connected in the handle housing (401), the handle housing (401) is exposed out of the gun body (007), the push rod (402) is located in the gun body (007) and is movably arranged along the length direction of the gun body (007), the handle housing (401) drives the push rod (402) to move synchronously when being driven, and the push rod (402) is used for pushing the driving member (006) to slide towards the first position and driving the gyroscope (002) to rotate and accelerate.

6. The gyrotron gun as claimed in claim 5, further comprising a gyrotron accelerator (403), wherein the gyrotron accelerator (403) is fixed in the gun body (007), and the push rod (402) is engaged with the gyrotron accelerator (403);

the driving piece (006) is including supplying top seat (601) that top (002) was placed, but top seat (601) rotation relatively ground is connected on driving piece (006), top seat (601) lower extreme be equipped with rotary gear (612) with top accelerator (403) meshing, acceleration state, push rod (402) are followed during the length direction reciprocating motion of rifle body (007) drive top accelerator (403) continue to give top seat (601) and be located top (002) on top seat (601) rotation acceleration.

7. The spinning gun according to claim 6, characterized in that the driving member (006) is mounted in the gun body (007) by means of the driving elastic member (603), the driving elastic member (603) is charged when the triggering assembly (005) locks the driving member (006), and the driving elastic member (603) is discharged to slide the driving member (006) from the first position toward the second position when the triggering assembly (005) unlocks the driving member (006).

8. The spinning gun according to claim 2, wherein said driving member (006) further comprises a thimble (611), said thimble (611) being located at the bottom of said driving position and being movable in a direction in which said spinning top (002) is disengaged from said driving member (006);

the front end of the gun body (007) is provided with a launching guide surface (711) which gradually inclines upwards in the direction of ejecting the gun body (007) towards the spinning top (002), and when the lower end of the driving piece (006) slides to the launching guide surface (711), the ejector pin (611) is guided by the launching guide surface (711) to be ejected upwards so as to push the spinning top (002) out of the gun body (007).

9. The gyrotron as claimed in claim 2, wherein the loading assembly (003) is located between the magazine (001) and the drive member (006), a radial direction of the gyro (002) in the magazine (001) being perpendicular to a length direction of the gun body (007);

when the drive piece (006) triggers the loading assembly (003), the loading assembly (003) grabs the foremost one of the magazines (001) and the gyro (002) swings backwards to the radial direction of the gyro (002) parallel to the length direction of the gun body (007), and the gyro (002) is placed on the drive position of the drive piece (006).

10. The spinning gun according to claim 9, characterized in that said upper bore assembly (003) comprises a collar (311), a rotary push (312) and a collar energy accumulator (313), said rotary push (312) being connected at a lower end of said collar (311), said collar energy accumulator (313) being connected between said collar (311) and said rotary push (312);

when the driving handle (004) is driven, the driving handle (004) drives the driving piece (006) to push the rotary push piece (312), the rotary push piece (312) drives the collar (311) to swing from a preparation position which is radial and perpendicular to the length direction of the gun body (007) to a loading position which is radial and parallel to the length direction of the gun body (007), and meanwhile, the collar energy storage piece (313) stores energy;

when the energy storage part (313) releases energy, the lantern ring (311) is driven to swing from the loading position to the preparation position.

11. The spinning gun according to claim 10, characterized in that a collar lock (300) is further mounted on the collar (311) for locking the spinning top (002) in the collar (311), and when the collar (311) is swung to the upper chamber position, the collar lock (300) unlocks the spinning top (002), and the spinning top (002) falls in the driving position of the driving member (006).

12. The gyroscopic gun according to claim 10, wherein the loading assembly (003) further comprises a top stopper (307), the top stopper (307) being rotatably mounted between the collar (311) and the magazine (001);

when the driving handle (004) drives the driving piece (302), the top stopper (307) is pushed to be partially shielded between the lantern ring (311) and the magazine (001).

13. The spinning gun according to claim 1, characterized in that said trigger assembly (005) comprises a cooperating trigger (501) and an actuating lock bar (502);

when the driving handle (004) is driven, the driving handle (004) pushes the driving piece (006) to slide to the position of the driving lock rod (502), and the driving lock rod (502) locks the driving piece (006);

when the trigger (501) is triggered, the trigger (501) pushes the driving lock rod (502) to unlock the driving piece (006).

14. The spinning gun according to any one of claims 1 to 13, characterised in that said magazine (001) comprises a magazine barrel (101) for housing at least two of said gyros (002) and a top lock (102) and a resilient pusher (103) mounted in said magazine barrel (101);

the elastic pushing piece (103) is arranged in the magazine barrel (101) and is used for pushing the spinning top (002) to the opening position of the magazine barrel (101);

the top lock (102) is located in an open position of the magazine barrel (101), the top lock (102) being used to lock the top (002) within the magazine barrel (101);

when the top lock (102) is triggered, the top (002) is unlocked, and the elastic pushing piece (103) pushes the top (002) at the most front end out of the magazine barrel (101).

15. The gyroscopic gun according to claim 14, wherein the gyroscopic lock (102) comprises a locking catch (121) and a striker (122), part of the locking catch (121) being movably inserted into the magazine cartridge (101) for locking the top (002) in the magazine cartridge (101), the striker (122) cooperating with the locking catch (121) and partly protruding out of the magazine cartridge (101);

when the striking piece (122) is triggered, the locking buckle (121) releases the locking of the spinning top (002), and the elastic pushing piece (103) pushes the spinning top (002) out of the opening of the magazine barrel (101).

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