CN217526351U - Emitter and top toy - Google Patents

Abstract

The application discloses a transmitter, which comprises a plug-in and a sleeve piece, wherein the sleeve piece is sleeved on the plug-in a pluggable manner, the plug-in is provided with a rotary driving component for driving a rotary body to rotate and an ejection component for ejecting the rotary body out, and a transmission component is arranged between the plug-in and the sleeve piece; the transmission assembly comprises a linkage part and a transmission shaft, the linkage part is connected with the external member, the transmission shaft is rotatably arranged on the plug-in unit, the first end of the transmission shaft is in transmission connection with the rotary driving assembly, and the linkage part is in linkage with the second end of the transmission shaft; when the external member is plugged relative to the plug-in unit, the linkage part drives the transmission shaft to rotate, and the transmission shaft drives the rotation driving assembly to rotate so as to drive the rotating body to rotate. The application also discloses a top toy. This application can enough combine the rotator with the rotator drive with higher speed and transmission, also can play as plug-in components and external member alone, and the method of playing is various, and is interesting strong, this application simple structure simultaneously, convenient operation.

Description

Emitter and top toy

Technical Field

The application relates to the technical field of toys, in particular to a launcher and a top toy.

Background

The existing top launcher in the market is usually made into a box shape or a gun shape, an inserting hole for inserting a brace or a pull ring for pulling a rope and a connecting part for installing a top are arranged on the launcher, a player generally only can use the top launcher as a tool for launching the toy top, and the launcher has no characteristic of independent play and lacks freshness and surprise.

The existing gyroscope emitter which is made like a sword is characterized in that a scabbard is made into the emitter, and then a handle is arranged at the tail end of a rack which drives the gyroscope to rotate so that the rack forms the shape of a sword body; some of the spinning tops have only the sword body without the sword sheath, then the spinning top is arranged in the sword body, and the sword blade part of the sword body is separated left and right after the spinning top is driven to be ejected. The above gyro launchers are not driven to rotate by sleeving the sword sheaths on the gyro launchers, but the driving modes adopted by the above gyro launchers are the same as those of other existing gyro launchers, so that the fun is lacked, the gyro is not observed on the sword body of a main playing part, or even the gyro is not observed on the sword body, and the function and the fun of combining the sword body and the gyro for playing are lacked.

Therefore, it is desirable to design a launcher and a top toy that can be played with a top as well as alone.

SUMMERY OF THE UTILITY MODEL

The application aims to overcome the defects of the prior art and provide the launcher and the top toy, the rotator can be driven to accelerate and launch by combining with the rotator, the plug-in and the external member can be independently used for playing, the playing method is various, and the interestingness is strong; and simple structure, convenient operation.

The technical scheme of the application provides a transmitter, which comprises a plug-in component and a sleeve component, wherein the sleeve component is sleeved on the plug-in component in a pluggable manner, the plug-in component is provided with a rotary driving component for driving a rotary body to rotate and an ejection component for ejecting the rotary body, and a transmission component is arranged between the plug-in component and the sleeve component;

the transmission assembly comprises a linkage part and a transmission shaft, the linkage part is connected with the sleeve, the transmission shaft is rotatably arranged on the plug-in component, the first end of the transmission shaft is in transmission connection with the rotary driving assembly, and the linkage part is in linkage with the second end of the transmission shaft;

when the external member is plugged in and pulled out relative to the plug-in unit, the linkage part drives the transmission shaft to rotate, and the transmission shaft drives the rotation driving assembly to rotate so as to drive the rotating body to rotate.

Preferably, the linkage part is a plurality of oblique racks arranged at intervals, the oblique direction of the oblique racks and the plugging direction of the external member relative to the plugging member form an acute included angle, the second end of the transmission shaft is fixedly connected with a column wheel, and the oblique racks are matched with the column wheel;

when the external member is plugged in and pulled out relative to the plug-in unit, the helical rack drives the column wheel to rotate, and the column wheel drives the transmission shaft to rotate.

Preferably, the column wheel comprises a plurality of columns evenly arranged at circumferentially spaced intervals around the drive shaft;

when the column wheel is matched with one of the bevel racks, the bevel rack is positioned between two adjacent convex columns, when the column wheel moves along the plugging direction, the convex columns slide along the inclination direction of the bevel rack and rotate, and the convex columns rotate to drive the transmission shaft to rotate;

when the former convex column is separated from the former bevel rack, the adjacent latter convex column is contacted with the adjacent latter bevel rack.

Preferably, the transmission shaft is a screw rod, the linkage part is a nut, the nut is fixed on the sleeve, and the screw rod is in threaded fit with the nut;

when the sleeve is plugged in and pulled out relative to the plug-in unit, the screw rod slides relative to the nut and rotates through threaded fit.

Preferably, the transmission shaft is provided with a spiral groove circumferentially arranged around the transmission shaft, the linkage part is a lug arranged on the sleeve, and the lug is connected in the spiral groove in a sliding manner;

when the sleeve is plugged relative to the plug-in unit, the lug slides along the spiral groove and drives the transmission shaft to rotate.

Preferably, the transmission shaft is provided with a wave-shaped groove arranged around the circumference of the transmission shaft, the linkage part is a lug arranged on the sleeve, and the lug is connected in the wave-shaped groove in a sliding manner;

when the sleeve is plugged relative to the plug-in unit, the lug slides along the wave-shaped groove and drives the transmission shaft to rotate.

Preferably, the card connector further comprises a limiting component for limiting the separation of the rotating body and the rotating driving component, and the limiting component is arranged on the card connector.

Preferably, the insert comprises an emission opening;

when the rotating body is driven, the rotating body is limited in the transmitting opening by the limiting assembly, and the rotating driving assembly drives the rotating body to rotate;

during the transmission, spacing subassembly unblock, the subassembly drive of launching the rotator is followed the transmission mouth launches.

Preferably, the rotary driving assembly comprises an input gear and a clutch gear, the input gear is in transmission connection with the transmission shaft, the input gear is in transmission connection with the clutch gear, the clutch gear is movably arranged on the plug-in component, and the rotating body is provided with a transmission gear;

when the plug-in unit and the sleeve are relatively pulled out, the clutch gear is in transmission connection with the transmission gear;

when the plug-in unit and the external member are relatively inserted, the clutch gear is separated from the transmission gear, and no transmission is performed between the clutch gear and the transmission gear.

The utility model also discloses a top toy, including top and foretell transmitter.

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

the plug-in components and the external members can be pulled out and inserted relatively, so that a sword-shaped toy can be simulated for playing, the transmitter can be played independently, meanwhile, the plug-in components and the external members can be combined with the rotating body for playing, the plug-in components and the external members are pulled out and inserted relatively to drive the rotary driving assembly to move, the rotating body is driven to rotate through the rotary driving assembly, and then the rotating body is emitted through the ejection assembly, so that the plug-in components and the external members can be combined with the rotating body for playing and can be played independently, the playing method is various, and the interestingness is strong; and this application adopts linkage portion and transmission shaft matched with transmission mode, compares in current rack and gear drive or stay cord and rope sheave driven mode, and this transmission mode is used on this kind of driving top transmitter of formula drive of nesting for this transmission mode's structure is more simple, and the external member is inserting or when breaking away from the sword body completely and extracting in addition, can not influence the holistic molding of toy, and the operation when emboliaing the external member on the plug-in components simultaneously is also simple swift, can not have the hindrance sense.

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 the present invention in one embodiment in combination with an insert and a kit;

FIG. 2 is a schematic view of the present invention with the insert and the sleeve separated in one embodiment;

fig. 3 is a schematic view of the present invention showing the transmission assembly in one embodiment thereof;

fig. 4 is a schematic view of the locking structure of the present invention in one embodiment;

fig. 5 is a schematic view of the rotary drive assembly of the present invention in one embodiment thereof;

fig. 6 is a schematic diagram of the present invention in one embodiment with the transmitter in a first configuration;

fig. 7 is a schematic diagram of the transmitter in a second configuration in one embodiment of the invention;

fig. 8 is a schematic view of the limiting assembly in a blocking state according to one embodiment of the present invention;

fig. 9 is a schematic diagram illustrating the connection between the limiting component and the ejection component according to one embodiment of the present invention;

fig. 10 is a schematic connection diagram of the stopper and the ejection assembly according to an embodiment of the present invention;

fig. 11 is a schematic diagram of the limiting assembly in a release state according to one embodiment of the present invention.

Reference numerals comparison table:

the plug-in 1:

the launching seat 10: an emitting opening 100, a guide groove 101;

the ejection assembly 11: a slide block 111, a third elastic member 112, a wing plate 113, a communication port 114;

the rotary drive assembly 12: a clutch gear 121, an input gear 122, a transition gear set 123;

the limiting component 13: the door opening member 131, the movable arm 1311, the first elastic member 1312, the stopper 132, and the guide post 1321;

the locking assembly 14: a locking member 141, a triggering member 142, a fourth elastic member 143;

an insertion portion 15, a launching rail 151, a grip portion 16;

kit 2:

a clamping block 21, a control member 22, a locking opening 221, an unlocking opening 222 and a positioning block 23;

the transmission assembly 3:

a helical rack 31, a transmission shaft 32, a column wheel 321 and a convex column 3211.

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. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Throughout the description of the present application, it is to be noted that, unless otherwise expressly specified or limited, the terms "mounted," "connected," and "coupled" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; the two components can be directly connected or indirectly connected through an intermediate medium, and the two components can be communicated with each other. The foregoing may be understood as pertaining to the specific meaning of the present application as the case may be, to one of ordinary skill in the art.

The utility model discloses a transmitter in one of the embodiments, as shown in fig. 1 and fig. 2, it includes plug-in 1 and external member 2, the external member 2 is sleeved on the plug-in 1 in a pluggable way, as shown in fig. 6, the plug-in 1 is provided with a rotary driving component 12 for driving the rotation of the rotator and an ejection component 11 for transmitting the rotator, a transmission component 3 is arranged between the plug-in 1 and the external member 2;

as shown in fig. 3, the transmission assembly 3 includes a linkage portion and a transmission shaft 32, the linkage portion is connected to the sleeve 2, the transmission shaft 32 is rotatably disposed on the inserter 1, a first end of the transmission shaft 32 is in transmission connection with the rotary driving assembly 12, and the linkage portion is linked with a second end of the transmission shaft 32;

when the sleeve 2 is inserted into or pulled out of the plug-in unit 1, the linkage portion drives the transmission shaft 32 to rotate, and the transmission shaft 32 drives the rotation driving assembly 12 to rotate so as to drive the rotation body to rotate.

Furthermore, the inside of the sleeve 2 is provided with a containing cavity, part of the plug-in 1 can be inserted into the containing cavity and also can be pulled out of the containing cavity, and the plug-in 1 and the sleeve 2 can be separated from each other. Wherein, when plug-in components 1 inserts to the external member 2 in, linkage portion and transmission shaft 32 transmission are connected, consequently when plug-in components 1 and external member 2 plug relatively, can drive transmission shaft 32 through linkage portion and rotate, drive the action of rotary drive subassembly 12 through transmission shaft 32 simultaneously to make rotary drive subassembly 12 can drive the rotator and rotate, and can also outwards launch the rotator through launching subassembly 11, in order to realize that the drive rotator is rotatory and launch the rotator.

Wherein, the transmitter can play as the toy alone, and preferably, plug-in components 1 designs into sword body shape, and external member 2 designs into the scabbard shape, can mould fit sword state when being about to plug-in components 1 inserts to external member 2 in, extracts plug-in components 1 from external member 2, can simulate and pull out the sword state. Meanwhile, the plug-in 1 can be taken out and played independently, so that the playing method of the toy is diversified, a player can be attracted better, and the vitality of the toy product is improved.

In addition, this application cooperates through linkage portion and transmission shaft 32 for holistic transmission structure is simpler, thereby can utilize plug-in components 1 and the space of external member 2 more efficiently, can not destroy the molding structure of toy promptly, also can simplify the structure. Simultaneously the transmission structure of this application for the transmission mode of current rack and gear drive or stay cord and rope sheave, the transmission structure of this application can combine together with the toy molding well for the toy is whole more pleasing to the eye. Meanwhile, the operation of sleeving the sleeve 2 into the plug-in 1 is simple and quick, and the blocking feeling can not be generated, so that the playing process of a player is smoother.

Further, as shown in fig. 2, the insert 1 includes an insertion portion 15, a launching seat 10 and a holding portion 16, wherein the launching seat 10 connects the insertion portion 15 and the holding portion 16, when the insert 1 is inserted into the set 2, the insertion portion 15 is inserted into the accommodating cavity of the set 2, and the launching seat 10 and the holding portion 16 are located outside the accommodating cavity. Wherein the rotary drive assembly 12 and the ejection assembly 11 are arranged on the launching pad 10 and the transmission shaft 32 is arranged on the insertion portion 15.

As shown in fig. 6, an emitting opening 100 for accommodating the rotator is formed in the emitting base 10, when the rotator is driven to rotate, the rotator is loaded into the emitting opening 100, at this time, the rotator is in transmission connection with the rotation driving component 12, and the transmission shaft 32 is driven to rotate through the plug-in/plug-out module 1 and the sleeve 2, and the transmission shaft 32 drives the rotation driving component 12 to move so as to drive the rotator to rotate. When the launcher is launched, the rotating body in the launching port 100 is launched outwards through the launching mechanism.

Preferably, as shown in fig. 1, when the insert 1 is inserted into the set 2, the transmission opening 100 is located outside the receiving cavity, and the rotating body loaded into the transmission opening 100 can be located outside the receiving cavity, so that the rotating body does not interfere with the set 2, and the rotating body can also be used as part of the appearance of the transmitter.

Alternatively, the insert 1 and the sleeve 2 can be designed in other different shapes to meet different player requirements, for example, the insert 1 can be designed in a magic wand shape to meet female player requirements.

Further, a locking structure is provided between the insert 1 and the sleeve 2, and the insert 1 and the sleeve 2 can be locked by the locking structure, so that the insert 1 is fixed relative to the sleeve 2 after being inserted into the sleeve 2.

As shown in fig. 4, the locking structure includes a fixture block 21 and a bayonet (not shown), the fixture block 21 is movably disposed on the sleeve 2, the bayonet is disposed on the plug-in unit 1, and when the plug-in unit 1 is inserted into the sleeve 2, the fixture block 21 is clamped into the bayonet, so that the plug-in unit 1 and the sleeve 2 are relatively fixed and cannot be separated from each other.

Still further, as shown in fig. 4, the locking structure further includes a control member 22, the control member 22 is movably disposed on the casing member 2, a positioning block 23 is disposed on the casing member 2, a locking opening 221 and an unlocking opening 222 are disposed on the control member 22, and the control member 22 has a wedge portion. During unlocking, the user moves the control member 22 to the positioning block 23 to be clamped into the unlocking opening 222, at this time, the control member 22 is separated from the clamping block 21, and the clamping block 21 is separated from the clamping opening, so that the plug-in unit 1 and the sleeve unit 2 can move relatively. When locking, the user moves the control member 22 to the positioning block 23 to be snapped into the locking opening 221, and the wedge portion on the control member 22 pushes the snapping block 21 to be snapped into the snapping opening, so that the insert 1 and the sleeve 2 are relatively fixed.

In some embodiments of the present invention, as shown in fig. 3, the linkage portion is a plurality of angular racks 31 arranged at intervals, an acute included angle is formed between an inclined direction of the angular rack 31 and a plugging direction of the external member 2 relative to the plugging direction of the plug-in unit 1, a column wheel 321 is fixedly connected to the second end of the transmission shaft 32, and the angular racks 31 are matched with the column wheel 321;

when the sleeve 2 is inserted into or pulled out of the plug-in unit 1, the helical rack 31 drives the column wheel 321 to rotate, and the column wheel 321 drives the transmission shaft 32 to rotate.

Further, the helical rack 31 is arranged on the inner wall of the sleeve 2, the helical rack 31 is arranged along the plugging direction, the column wheel 321 is arranged at one end, away from the launching seat 10, of the plug-in unit 1, the first end of the helical rack 31 is arranged at one side close to the opening of the accommodating cavity, the second end of the helical rack 31 is arranged at the other side away from the opening of the accommodating cavity, when the plug-in unit 1 is plugged into the sleeve 2, the column wheel 321 moves from the first end to the second end of the helical rack 31, and when the plug-in unit 1 is plugged out of the sleeve 2, the column wheel 321 moves from the second end to the first end of the helical rack 31.

In some embodiments of the present invention, as shown in fig. 3, the column wheel 321 includes a plurality of protruding columns 3211 uniformly circumferentially spaced around the transmission shaft 32;

when the column wheel 321 is matched with one of the racks 31, the rack 31 is located between two adjacent convex columns 3211, when the column wheel 321 moves along the plugging direction, the convex columns 3211 slide along the oblique direction of the rack 31 and rotate, and the convex columns 3211 rotate to drive the transmission shaft 32 to rotate;

when the previous convex pillar 3211 is separated from the previous helical rack 31, the adjacent next convex pillar 3211 contacts the adjacent next helical rack 31.

Specifically, as shown in fig. 3, a plurality of convex pillars 3211 are respectively disposed on the circumferential surface of the transmission shaft 32 at regular intervals. When the plug-in 1 is inserted into the sleeve 2, at least one convex column 3211 contacts the helical rack 31, and when the plug-in 1 is relatively inserted into or pulled out of the sleeve 2, the convex column 3211 slides along the helical rack 31, and simultaneously the convex column 3211 drives the transmission shaft 32 to rotate under the action of the helical rack 31, so as to achieve the effect of driving the rotary driving assembly 12.

When the previous convex column 3211 is separated from the previous helical rack 31, the plug-in unit 1 is continuously inserted into or pulled out of the sleeve 2, that is, the next convex column 3211 can contact with the next helical rack 31, so that transmission can be continuously maintained between the column wheel 321 and the helical rack 31, and the transmission shaft 32 can be continuously driven to rotate.

In some optional embodiments of the present invention, the transmission shaft 32 is a lead screw, the linkage portion is a nut, the nut is fixed on the sleeve 2, and the lead screw is in threaded fit with the nut;

when the sleeve 2 is inserted into or pulled out of the plug-in unit 1, the screw rod slides relative to the nut and rotates through threaded fit.

The nut is fixedly connected to the sleeve 2, when the plug-in unit 1 is inserted into the sleeve 2, the nut is in transmission connection with the lead screw, and when the plug-in unit 1 and the sleeve 2 are relatively plugged in and pulled out, the lead screw is driven to rotate under the action of the nut, so that the rotary driving assembly 12 is driven to move.

In some optional embodiments of the present invention, the second end of the transmission shaft 32 is provided with a gear, the sleeve 2 is provided with a spur rack, and the plug-in unit 1 is provided with a reversing gear set, and the reversing gear set is engaged with the gear. When the plug-in unit 1 is inserted into the sleeve unit 2, the reversing gear set is meshed with the spur rack, and the spur rack is driven by the reversing gear set to rotate through the plug-in unit 1, so that the transmission shaft 32 is driven to rotate.

In some optional embodiments of the present invention, the transmission shaft 32 is provided with a spiral groove circumferentially arranged around the transmission shaft 32, the linkage portion is a projection arranged on the sleeve member 2, and the projection is slidably connected in the spiral groove;

when the cartridge 2 is inserted and extracted with respect to the insert 1, the projections slide along the helical grooves and drive the transmission shaft 32 in rotation.

Furthermore, an inlet and an outlet are formed in one side of the spiral groove close to the opening of the accommodating cavity, when the plug-in unit 1 is inserted into the sleeve 2, the convex block on the plug-in unit 1 enters the spiral groove from the inlet and the outlet, and when the plug-in unit 1 is continuously inserted into the sleeve 2, the convex block slides along the spiral groove to drive the transmission shaft 32 to rotate. Similarly, when the plug-in unit 1 is pulled out from the sleeve 2, the projection slides along the spiral groove to drive the transmission shaft 32 to rotate, and when the plug-in unit 1 needs to be completely pulled out of the sleeve 2, the projection is separated from the spiral groove from the inlet and the outlet of the spiral groove.

In some optional embodiments of the present invention, the transmission shaft 32 is provided with a wave-shaped groove disposed around the circumference of the transmission shaft 32, the linkage portion is a bump disposed on the sleeve member 2, and the bump is slidably connected in the wave-shaped groove;

when the cartridge 2 is inserted and extracted with respect to the insert 1, the lugs slide along the wave-shaped grooves and drive the drive shaft 32 in rotation.

Further, the wave shaped groove has an access opening from which the projections can enter the wave shaped groove when the insert 1 is inserted into the sleeve 2. When the plug-in unit 1 is inserted into or pulled out of the sleeve 2, the protrusions slide along the wave-shaped grooves and drive the transmission shaft 32 to rotate. Since the wave-shaped grooves are formed around the circumferential direction of the drive shaft 32, the protrusions can drive the drive shaft 32 to rotate in the same direction when the card 1 is inserted into the cartridge 2 or when the card 1 is removed from the cartridge 2, and thus a player can continuously drive the rotary body to rotate by repeatedly inserting and removing the card 1 or the cartridge 2.

Alternatively, the wave-shaped grooves are closed and continuously provided on the circumferential surface of the drive shaft 32, and the projections are always held in the wave-shaped grooves. I.e. the insert 1 always remains connected to the sleeve 2.

In some embodiments of the present invention, as shown in fig. 6, a limiting component 13 is further included for limiting the separation of the rotating body from the rotating driving component 12, and the limiting component 13 is disposed on the insert 1.

In some embodiments of the present invention, the insert 1 comprises an emission opening 100;

when the rotary body is driven, the rotary body is limited in the transmitting opening 100 by the limiting assembly 13, and the rotary driving assembly 12 drives the rotary body to rotate;

when the launching is carried out, the limiting component 13 is unlocked, and the ejection component 11 drives the rotating body to be launched out from the launching port 100.

Further, the card 1 further includes a launching track 151, the launching track 151 is disposed along a launching direction, and the launching track 151 is communicated with the launching port.

As shown in fig. 2, the launching track 151 is disposed on the insertion portion 15, an entrance end of the launching track 151 is communicated with the launching port 100, an exit end of the launching track 151 is communicated with the outside, and during launching, the rotator is ejected from the launching port 100, enters the launching track 151 along the exit end, and slides along the launching track 151 to be separated from the launching base 10 along the exit end. Wherein the launching track 151 is a linear track. The launching track 151 can further guide the traveling track of the rotating body after launching, and the controllability of the toy is improved.

Alternatively, the launching track 151 may also be an arc track through which the launching path of the rotator may be changed, i.e., the rotator may be enabled not only to travel in a straight line but also to turn after being launched.

Optionally, a jump platform is arranged on the launching track 151, and the rotating body flies upwards away from the launching track 151 through the jump platform after being launched, so that the rotating body is not blocked by the sleeve 2 from being launched when the plug-in 1 and the sleeve 2 are not separated.

Further, the emitter at least comprises a first state and a second state, and the limiting assembly 13 comprises a blocking state and a releasing state.

As shown in fig. 6, during driving, the ejection assembly 11 stores energy, the launcher is in the first state, the limiting assembly 13 is in a blocking state and limits the rotating body in the launching port 100, and the rotation driving assembly 12 drives the rotating body to rotate;

as shown in fig. 7, when the rotating body is launched, the launching assembly 11 releases energy, the launching assembly 11 drives the limiting assembly 13 to switch to the release state, the launcher is changed to the second state, and the rotating body is launched outwards from the launching port 100 by the launching assembly 11.

Further, when the device is driven, the rotating body is installed in the launching opening 100 and keeps transmission connection with the rotation driving assembly 12, the rotating body is driven by the rotation driving assembly 12 to rotate and accelerate, meanwhile, the limiting assembly 13 is in a blocking state, and the limiting assembly 13 limits the rotating body in the launching opening 100, so that the rotating body and the rotation driving assembly 12 keep transmission in the driving process, and the rotating body is prevented from being separated from transmission in the driving process to cause that the rotating body cannot reach the rotating speed required by a player or influence subsequent launching. When the launching device is used for launching, the ejection component 11 releases the energy to act and is linked with the limiting component 13 to act, so that the limiting component 13 is switched from a blocking state to a releasing state, and at the moment, the ejection component 11 releases the energy and drives the rotating body to be launched outwards from the launching port 100.

As shown in fig. 6, when the limiting assembly 13 is in the blocking state, the limiting assembly 13 blocks the emitting direction of the rotating body, so that the rotating body cannot be separated from the emitting opening 100 towards the emitting direction, and when the limiting assembly 13 is in the releasing state, the limiting assembly 13 leaves the emitting direction of the rotating body, so that the ejecting assembly 11 can drive the rotating body to be ejected outwards from the emitting opening 100 towards the emitting direction.

When spacing subassembly 13 is in the state of blockking, the transmitter is in first form, as shown in fig. 7, and when the transmission, spacing subassembly 13 switches to the state of letting pass, makes the transmitter transform to the second form simultaneously, consequently in the emission process, the transmitter can realize the linkage with the emission process and warp to can improve the interest and the object for appreciation nature of toy. Meanwhile, the emitter can deform, so that the emitter can be independently played as a toy, and the playing method of the toy is increased.

Further, as shown in fig. 8, the ejection assembly 11 includes a sliding block 111 and a third elastic member 112, the sliding block 111 is slidably disposed on the launching seat 10, and the third elastic member 112 is connected between the launching seat 10 and the sliding block 111, wherein the sliding block 111 can slide toward the launching direction. When the driving mechanism is driven, the sliding block 111 is in the first position and compresses the third elastic element 112, and the third elastic element 112 is in the energy storage state. When the gun is fired, the third elastic element 112 releases energy and pushes the sliding block 111 to slide towards the firing direction, the sliding block 111 slides from the first position to the second position, and the sliding block 111 pushes the rotating body in the firing opening 100 to be separated from the firing opening 100 towards the firing direction.

Specifically, as shown in fig. 8, the limiting component 13 is linked with the sliding block 111, and when the sliding block 111 is in the first position, the limiting component 13 is in the blocking state and limits the rotating body in the emission opening 100, so that the rotating body can keep transmitting with the rotation driving component 12, and further, the rotating body can be continuously accelerated. As shown in fig. 9, during launching, the sliding block 111 slides from the first position to the second position, and the sliding block 111 is linked with the limiting component 13 and switches from the blocking state to the releasing state, so that the limiting component 13 leaves the launching direction of the rotating body, and further the sliding block 111 can push the rotating body to launch outwards in the launching direction. Meanwhile, the limiting assembly 13 acts to enable the device to be switched from the first form to the second form, so that deformation can be achieved in the launching process, and playability and interestingness of the toy are improved.

Optionally, the ejection assembly 11 may further include an ejection rod rotatably connected to the launching seat 10, and a spring connected between the ejection rod and the launching seat 10. When driving, the spring stores energy. When the projectile is launched, the spring releases energy and drives the ejection rod to rotate, and the ejection rod is in contact with the rotating body in the launching port 100 and pushes the projectile to be launched out towards the launching direction.

Wherein, the spring can be a compression spring or a torsion spring.

Further, as shown in fig. 7, one side of the emission opening 100 facing the emission direction is open, a part of the rotation driving assembly 12 extends into the emission opening 100 and can be in transmission connection with the rotating body in the emission opening 100, and during driving, the limiting assembly 13 blocks the rotating body from being separated from the emission opening 100, so that the rotating body can be kept in transmission connection with the rotation driving assembly 12. When the launcher is launched, the limiting component 13 moves to a direction away from the launching direction, so that the ejection component 11 can drive the rotating body to eject out of the launching port 100 towards the launching direction.

In some embodiments of the present invention, as shown in fig. 8, the limiting component 13 includes a door opening component 131, the door opening component 131 is movably connected to the launching seat 10, and a linkage component is arranged on the door opening component 131 and is linked with the ejection component 11;

as shown in fig. 8, the door opening piece 131 blocks in the discharging direction of the rotating body and restricts the rotating body in the discharging opening 100 at the time of driving;

as shown in fig. 11, during launching, the ejection assembly 11 drives the linkage member to move, the linkage member drives the door opening member 131 to move in the direction away from the launching direction, and the ejection assembly 11 drives the rotating body to launch in the launching direction.

Further, the linkage is connected between the door opening piece 131 and the sliding block 111 of the ejection assembly 11, and when the ejection assembly 11 acts, the linkage can drive the door opening piece 131 to move, so that the door opening piece 131 is switched between the blocking state and the releasing state. Wherein, in the blocking state, at least a portion of the door opening member 131 is blocked in the firing direction of the rotating body, and the door opening member 131 is in contact with the rotating body, so that the rotating body is confined in the firing port 100. During the transmission, launch subassembly 11 and release energy, sliding block 111 slides and promotes the rotator and launches towards the transmission direction, and simultaneously, sliding block 111 drives the action of opening door piece 131 through the link for opening door piece 131 leaves the transmission direction of rotator, and the rotator just can launch from transmission mouth 100 this moment.

In some embodiments of the present invention, as shown in fig. 8 and 11, the linkage member includes a movable arm 1311, the door opening member 131 is rotatably connected to the launching seat 10, one end of the movable arm 1311 is linked to the launching assembly 11, the other end of the movable arm 1311 is fixedly connected to the door opening member 131, and a first elastic member 1312 is disposed between the movable arm 1311 and the launching seat 10;

as shown in fig. 8, when actuated, the first elastic element 1312 actuates the movable arm 1311 to move, and the movable arm 1311 brings the door opening element 131 to remain blocked in the launching direction;

as shown in fig. 11, during firing, the ejection assembly 11 drives the movable arm 1311 to move, the first elastic member 1312 compresses, and the movable arm 1311 drives the door opening member 131 to move in the direction away from the firing direction.

Further, as shown in fig. 9, the door opening member 131 is coaxial with the movable arm 1311, one end of the door opening member 131 is a hinged end, the other end is a limiting end, one end of the movable arm 1311 is a hinged end, the other end is a touch end, the hinged end of the door opening member 131 is fixedly connected with the hinged end of the movable arm 1311 and is rotatably connected with the launching seat 10, and the touch end of the movable arm 1311 contacts with the sliding block 111 of the launching assembly 11.

Still further, first elastic element 1312 is a compression spring, and one end of first elastic element 1312 is connected to launching pad 10, and the other end is connected to movable arm 1311 and is capable of driving movable arm 1311 to rotate around its rotation axis, so that the touching end of movable arm 1311 is kept in contact with sliding block 111.

Alternatively, the first elastic member 1312 may be a torsion spring provided at the hinge end of the movable arm 1311.

When the rotating body is driven, the sliding block 111 is located at the first position, and at this time, the movable arm 1311 is kept in contact with the sliding block 111 under the action of the first elastic element 1312, and simultaneously, the movable arm 1311 drives the door opening element 131 to rotate, so that the limiting end of the door opening element 131 moves to the launching direction of the rotating body, and the rotating body is further prevented from being separated from the launching port 100.

When the door is launched, the spring releases energy and pushes the sliding block 111 to slide in the launching direction, the sliding block 111 pushes the touch end of the movable arm 1311, so that the movable arm 1311 rotates, the movable arm 1311 drives the door opening piece 131 to rotate, the limiting end of the door opening piece 131 leaves the launching direction, and the rotating body can be launched in the launching direction.

Still further, when launching, the door opening piece 131 rotates outwards and expands, so that the launcher can be switched from the first form to the second form, the launching process can be in linkage deformation, and the interestingness of the toy is improved.

Optionally, the linkage comprises a movable arm 1311, one end of the movable arm 1311 is fixedly connected to the door opener 131, and the other end of the movable arm 1311 is hinged to the ejection assembly 11;

when driven, the ejection assembly 11 is in the first position, and the door opening member 131 blocks in the launching direction;

when the door is launched, the ejection assembly 11 moves in the launching direction and moves from the first position to the second position, the ejection assembly 11 drives the movable arm 1311 to rotate, and the movable arm 1311 drives the door opening member 131 to rotate in the direction away from the launching direction.

Further, the contact end of the movable arm 1311 is hinged to the sliding block 111, and when the sliding block 111 slides, the sliding block 111 drives the movable arm 1311 to rotate, and the movable arm 1311 drives the door opening member 131 to rotate, so that the limit end of the door opening member 131 can block or release the rotating body.

Optionally, the door opening member 131 is linked with the slide block 111. Specifically, one end of the door opening member 131 is a limiting end, the other end is a linkage end, a hinge end is provided between the limiting end and the linkage end, the hinge end is rotatably connected with the launching seat 10, and the linkage end is hinged or in contact with the sliding block 111.

In some embodiments of the present invention, as shown in fig. 8, two sets of door openers 131 are provided;

as shown in fig. 8, when driving, the two sets of door opening members 131 are close to each other and cover the periphery of the rotating body, and at least part of the door opening members 131 is blocked in the launching direction;

as shown in fig. 11, at the time of firing, the two sets of door-opening members 131 are distanced from each other and allow the rotating body to be fired in the firing direction.

Further, the door opening members 131 are arc-shaped, two sets of door opening members 131 are symmetrically disposed on two sides of the launching port 100, and the door opening members 131 are rotatably connected with the launching seat 10. When the driving is performed, the two sets of door opening members 131 approach each other and are spliced into a complete circular ring structure and are wrapped on the periphery of the rotating body, so that the rotating body is limited to be separated from the transmitting opening 100. At the same time, the two sets of door opening members 131 are assembled together to form the first configuration. During launching, the two sets of door opening members 131 are rotated and opened relatively, so that the limiting ends of the door opening members 131 are away from the launching direction, and meanwhile, the two sets of door opening members 131 which are opened relatively form a second shape.

Optionally, two sets of door opening members 131 are slidably disposed on the launching seat 10, respectively, and the door opening members 131 are linked with the sliding block 111, wherein a wedge portion is disposed on one of the sliding block 111 or the door opening members 131, an elastic member is disposed between the door opening members 131 and the launching seat 10, during launching, the sliding block 111 pushes the two sets of door opening members 131 away from each other through the wedge portion, and during driving, the door opening members 131 approach each other under the elastic force of the elastic member.

Preferably, the door opening pieces 131 serve to block the upper portion of the rotating body, and two sets of door opening pieces 131 are combined to form a circular ring structure wrapped around the outer circumference of the rotating body when driven, that is, the rotation of the rotation body during driving is not affected by the restriction of the rotation body from the discharge opening 100.

In some embodiments of the present invention, as shown in fig. 8-11, the limiting component 13 further includes a limiting component 132, the limiting component 132 is movably connected to the launching base 10, and the launching component 11 is linked with the limiting component 132;

as shown in fig. 8, when driving, at least a part of the limiting member 132 extends into the launching port 100 and limits the rotating body to separate from the launching port 100 along the launching direction;

as shown in fig. 11, during launching, the ejection assembly 11 drives the limiting member 132 to move, and the limiting member 132 leaves the launching opening 100.

Further, as shown in fig. 9 and 10, the sliding block 111 of the ejection assembly 11 includes two sets of side wings 113 oppositely disposed on the side wings 113, the two sets of side wings 113 are respectively disposed on two sides of the emission opening 100, and a communication opening 114 is disposed on the side wings 113, wherein the limiting member 132 can enter into the emission opening 100 through the communication opening 114.

Preferably, two limiting members 132 are respectively disposed on two sides of the emission opening 100, the two limiting members 132 act synchronously, the limiting members 132 are linked with the sliding block 111, and the limiting members 132 have limiting ends, so that when the driving is performed, the limiting ends of the limiting members 132 extend into the emission opening 100 through the communication openings 114 and block in the emission direction of the rotating body, thereby limiting the rotating body in the emission opening 100. During launching, the sliding block 111 is linked with the limiting member 132 to move, so that the limiting end of the limiting member 132 leaves the launching port 100.

The limiting member 132 is disposed below the door opening member 131, and the limiting member 132 is used for limiting the lower portion of the rotating body.

In some embodiments of the present invention, as shown in fig. 9 and 10, the limiting member 132 is hinged to the ejection assembly 11, the limiting member 132 is provided with a guide post 1321, the launching seat 10 is provided with a guide slot 101, and the guide post 1321 is slidably disposed in the guide slot 101;

when the ejection assembly 11 is driven, the ejection assembly 11 is located at the first position and drives the guide post 1321 to slide to the first end of the guide slot 101, and at least part of the limiting member 132 extends into the middle emission opening 100 and limits the rotating body to be separated from the emission opening 100 along the emission direction;

when the launcher is launched, the ejection assembly 11 moves in the launching direction and moves from the first position to the second position, the ejection assembly 11 drives the limiting member 132 to move, the guide post 1321 slides from the first end to the second end of the guide slot 101, and the limiting member 132 leaves the launching port 100.

Furthermore, one end of the limiting member 132 is hinged to the sliding block 111, during launching, when the sliding block 111 slides towards the launching direction, the sliding block 111 drives the limiting member 132 to slide along the launching direction, and meanwhile, the limiting member 132 rotates towards a direction away from the launching port 100 under the guiding action of the guide post 1321 and the guide slot 101, so that the limiting end of the limiting member 132 leaves the launching port 100.

Optionally, the limiting member 132 is slidably disposed on the launching base 10, an elastic member is disposed between the limiting member 132 and the launching base 10, and during driving, the limiting end of the limiting member 132 extends into the launching port 100 under the action of the elastic member. During launching, the sliding block 111 pushes the limiting member 132 to slide in a direction away from the launching port 100, so that the limiting end of the limiting member 132 leaves the launching port 100.

Optionally, the limiting member 132 is not linked with the ejection assembly 11, and when the ejection assembly is driven, the limiting member 132 extends into the emission opening 100 under the action of the elastic member and limits the rotating body from being separated from the emission opening 100. When the firing is performed, the rotating body moves in the firing direction, and the rotating body pushes the stopper 132 to separate from the firing opening 100.

Optionally, a wedge-shaped portion is disposed on the limiting member 132, and a second elastic member is disposed between the limiting member 132 and the launching base 10;

when the driving is performed, at least part of the limiting member 132 driven by the second elastic member extends into the transmitting opening 100;

when firing, the ejection assembly 11 contacts the wedge and pushes the stopper 132 away from the firing port 100.

In some embodiments of the present invention, as shown in fig. 8, the present invention further includes a locking assembly 14, the locking assembly 14 includes a trigger 142 and a locking member 141, the trigger 142 is linked with the locking member 141;

when driven, the locking piece 141 is connected with the ejection assembly 11 and enables the ejection assembly 11 to keep energy storage;

when the ejection component 11 is fired, the trigger 142 drives the locking element 141 to act, the locking element 141 is separated from the ejection component 11, and the ejection component 11 releases energy.

Further, the locking member 141 has a locking end, wherein the locking end may be a locking hook, the locking member 141 is rotatably or slidably disposed on the launching base 10, a fourth elastic member 143 is disposed between the locking member 141 and the launching base 10, the fourth elastic member 143 may be a torsion spring or a compression spring, when the fourth elastic member is actuated, the sliding block 111 of the ejection assembly 11 moves to the first position, and the locking member 141 is under the elastic force of the fourth elastic member 143, the locking end of the locking member 141 is connected with the sliding block 111, so that the sliding block 111 cannot move. When the firing is performed, the locking member 141 is triggered by the trigger 142, so that the locking end of the locking member 141 is separated from the sliding block 111, and the sliding block 111 slides in the firing direction under the elastic force of the spring.

Preferably, as shown in fig. 8, the fourth elastic member 143 is a torsion spring, one end of the locking member 141 is rotatably connected to the launching seat 10, the other end of the locking member is provided with a locking hook, and the end of the locking member 141 connected to the launching seat 10 is provided with a torsion spring, which connects the locking member 141 and the launching seat 10. In driving, the latch hook is coupled to the sliding block 111 so that the sliding block 111 can be maintained in the first position. When the lock hook is released, the locking member 141 is rotated downward by the trigger 142, so that the lock hook is separated from the sliding block 111, and the sliding block 111 slides in the releasing direction by the third elastic member 112.

Further, the trigger 142 is movably disposed on the launching base 10, the trigger 142 contacts the locking element 141, and the trigger 142 drives the locking element 141 to move by pressing the trigger 142 downward, so that the locking end of the locking element 141 is separated from the sliding block 111 for unlocking.

In some embodiments of the present invention, as shown in fig. 5, the rotation driving assembly 12 includes an input gear 122 and a clutch gear 121, the input gear 122 is in transmission connection with the transmission shaft 32, the input gear 122 is in transmission connection with the clutch gear 121, the clutch gear 121 is movably disposed on the insert 1, and the rotating body is provided with a transmission gear;

when the plug-in unit 1 and the sleeve unit 2 are relatively pulled out, the clutch gear 121 is in transmission connection with the transmission gear;

when the insert 1 and the sleeve 2 are inserted relatively, the clutch gear 121 is separated from the transmission gear, and no transmission is performed between the clutch gear 121 and the transmission gear.

Further, as shown in fig. 5, the first end of the transmission shaft 32 is connected to the input gear 122, a transition gear set 123 is disposed between the input gear 122 and the clutch gear 121, and the reversing or the changing of the transmission ratio is realized through the transition gear set 123. Wherein, the clutch gear 121 is movably disposed on the launching seat 10, specifically, a sliding groove is disposed on the launching seat 10, and the clutch gear 121 is slidably disposed in the sliding groove.

When the plug-in 1 and the sleeve 2 are relatively pulled out, the transmission shaft 32 rotates towards the first direction, and at this time, the input gear 122 drives the clutch gear 121 to slide to the first end of the sliding groove, so that the clutch gear 121 can be engaged with the transmission gear of the rotating body, and further the rotating body is driven to rotate. When the plug-in 1 and the sleeve 2 are inserted relatively, the transmission shaft 32 rotates in a second direction opposite to the first direction, and at this time, the input gear 122 drives the clutch gear 121 to slide to the second end of the sliding groove, so that the clutch gear 121 is disengaged from the transmission gear, further no transmission is performed between the clutch gear 121 and the transmission gear, and the clutch gear 121 does not drive the rotating body to rotate reversely. By providing the clutch gear 121, the player can repeatedly pull and insert the insert 1 and the set 2 relative to each other, thereby continuously accelerating the rotating body.

As a preferred embodiment of the present invention, as shown in fig. 1-11, the launcher comprises a plug-in 1 and a sleeve 2, wherein the sleeve 2 is sleeved on the plug-in 1 in a pluggable manner, the plug-in 1 comprises an insertion portion 15 and a launching seat 10, the insertion portion 15 is connected with the launching seat 10, and the insertion portion 15 can be inserted into the sleeve 2. The launching base 10 is provided with a launching port 100 for accommodating the rotating body, the launching base 10 is provided with a rotary driving component 12 and an ejection component 11, a transmission component 3 is arranged between the plug-in component 1 and the sleeve component 2, the transmission component 3 comprises a linkage part and a transmission shaft 32, the linkage part is connected with the sleeve component 2, the transmission shaft 32 is rotatably arranged on the plug-in component 1, the first end of the transmission shaft 32 is in transmission connection with the rotary driving component 12, and the linkage part is in linkage with the second end of the transmission shaft 32.

The linkage part is provided with a plurality of oblique racks 31 which are arranged at intervals, the oblique direction of the oblique racks 31 and the plugging direction of the sleeve 2 relative to the plug-in unit 1 form an acute included angle, a column wheel 321 is arranged at the second end of the transmission shaft 32, and the oblique racks 31 are matched with the column wheel 321. The column wheel 321 includes a plurality of convex columns 3211, and the convex columns 3211 are respectively and uniformly disposed on the circumferential surface of the transmission shaft 32 at intervals. When the plug-in 1 is inserted into the sleeve 2, when the column wheel 321 is matched with one of the helical racks 31, the helical rack 31 is located between two adjacent convex columns 3211, and when the column wheel 321 moves along the plugging direction, the convex columns 3211 slide along the oblique direction of the helical rack 31 and rotate, and the convex columns 3211 rotate to drive the transmission shaft 32 to rotate, so as to achieve the effect of driving the rotary driving component 12.

When the previous convex column 3211 is separated from the previous helical rack 31, the plug-in unit 1 is continuously inserted into or pulled out of the sleeve 2, that is, the next convex column 3211 can contact with the next helical rack 31, so that transmission can be continuously maintained between the column wheel 321 and the helical rack 31, and the transmission shaft 32 can be continuously driven to rotate.

Further, the rotation driving assembly 12 includes an input gear 122 and a clutch gear 121, the input gear 122 is in transmission connection with the transmission shaft 32, the input gear 122 is in transmission connection with the clutch gear 121, the clutch gear 121 is movably disposed on the inserter 1, and a transmission gear is disposed on the rotating body.

When the plug-in 1 and the sleeve 2 are pulled out relatively, the transmission shaft 32 rotates towards the first direction, and at this time, the input gear 122 drives the clutch gear 121 to slide to the first end of the sliding groove, so that the clutch gear 121 can be meshed with the transmission gear of the rotating body, and the rotating body is driven to rotate. When the plug-in 1 and the sleeve 2 are inserted relatively, the transmission shaft 32 rotates in a second direction opposite to the first direction, and at this time, the input gear 122 drives the clutch gear 121 to slide to the second end of the sliding groove, so that the clutch gear 121 is disengaged from the transmission gear, further no transmission is performed between the clutch gear 121 and the transmission gear, and the clutch gear 121 does not drive the rotating body to rotate reversely. By providing the clutch gear 121, the player can repeatedly pull and insert the insert 1 and the set 2 relative to each other, thereby continuously accelerating the rotating body.

Further, the ejection assembly 11 includes a sliding block 111 and a third elastic member 112, the sliding block 111 is slidably disposed on the launching seat 10, and the third elastic member 112 is connected between the launching seat 10 and the sliding block 111. The locking assembly 14 includes a locking member 141 and a triggering member 142, one end of the locking member 141 is rotatably connected to the launching base 10, the other end is provided with a locking hook, the triggering member 142 is movably disposed on the launching base 10, the triggering member 142 is connected to the locking member 141, and the position of the sliding block 111 can be locked by the locking hook.

The limiting assembly 13 includes two door opening members 131, the two door opening members 131 are respectively disposed on two sides of the launching port 100, the door opening members 131 are rotatably connected to the launching seat 10, a movable arm 1311 is fixedly connected to the door opening members 131, a first elastic member 1312 is disposed between the movable arm 1311 and the launching seat 10, and an end of the movable arm 1311 is kept in contact with the sliding block 111 under the action of the first elastic member 1312.

The limiting component 13 further includes limiting members 132, two sets of limiting members 132 are respectively disposed on two sides of the launching port 100, wherein the limiting members 132 are hinged to the sliding block 111, the limiting members 132 are provided with guide posts 1321, the launching base 10 is provided with a guide slot 101, and the guide posts 1321 are slidably disposed in the guide slot 101.

When the rotary body is driven, the rotary body is loaded into the launching opening 100, the sliding block 111 is located at the first position, the third elastic element 112 stores energy, the locking hook is connected with the sliding block 111, so that the sliding block 111 is kept at the first position, at the moment, the two groups of door opening elements 131 are relatively close to each other under the action of the first elastic element 1312 and form a ring-shaped structure covering the periphery of the rotary body, and the door opening elements 131 block in the launching direction of the rotary body, so that the rotary body can be kept in the launching opening 100. Meanwhile, when the sliding block 111 is at the first position, the limiting end of the limiting member 132 extends into the transmitting opening 100, and the rotating body can be further limited from being separated from the transmitting opening 100 by the limiting member 132. The transmission gear on the rotating body is kept meshed with the clutch gear 121 in the rotating drive assembly 12, and the rotating body is driven to rotate in an accelerated manner by the rotating drive assembly 12. When actuated, the emitter is in a first configuration.

When the player launches, the player drives the locking member 141 to move through the trigger 142, so that the locking hook on the locking member 141 is separated from the sliding block 111, the third elastic member 112 releases energy and drives the sliding block 111 to slide towards the launching direction, and the sliding block 111 slides from the first position to the second position. The sliding block 111 pushes the movable arm 1311 to rotate while acting, and the movable arm 1311 drives the door opening members 131 to rotate, so that the two door opening members 131 are respectively opened towards the directions away from each other, and the door opening members 131 are not blocked in the launching direction of the rotating body. In addition, the sliding block 111 acts to drive the limiting member 132 to move, the limiting member 132 rotates under the action of the guide post 1321 and the guide slot 101 until the limiting end of the limiting member leaves the transmitting opening 100, and at this time, the sliding block 111 pushes the rotating body, so that the rotating body can be transmitted out from the transmitting opening 100. At this time, the transmitter is transformed from the first form to the second form.

The utility model also discloses a top toy, including top and foretell transmitter.

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 (10)

1. The launcher is characterized by comprising an insert (1) and a sleeve (2), wherein the sleeve (2) is sleeved on the insert (1) in a pluggable manner, a rotary driving component (12) for driving a rotary body to rotate and an ejection component (11) for launching the rotary body are arranged on the insert (1), and a transmission component (3) is arranged between the insert (1) and the sleeve (2);

the transmission assembly (3) comprises a linkage part and a transmission shaft (32), the linkage part is connected with the kit (2), the transmission shaft (32) is rotatably arranged on the plug-in (1), a first end of the transmission shaft (32) is in transmission connection with the rotary driving assembly (12), and the linkage part is in linkage with a second end of the transmission shaft (32);

when the sleeve (2) is plugged in and pulled out relative to the plug-in unit (1), the linkage part drives the transmission shaft (32) to rotate, and the transmission shaft (32) drives the rotary driving component (12) to rotate so as to drive the rotary body to rotate.

2. The launcher according to claim 1, wherein the linkage part is a plurality of oblique racks (31) arranged at intervals, the oblique direction of the oblique racks (31) forms an acute included angle with the inserting and pulling direction of the sleeve (2) relative to the inserting and pulling of the plug-in unit (1), the second end of the transmission shaft (32) is fixedly connected with a column wheel (321), and the oblique racks (31) are matched with the column wheel (321);

when the sleeve (2) is plugged in and pulled out relative to the plug-in unit (1), the oblique rack (31) drives the column wheel (321) to rotate, and the column wheel (321) drives the transmission shaft (32) to rotate.

3. The launcher according to claim 2, wherein the column wheel (321) comprises a plurality of columns (3211) evenly spaced circumferentially around the drive shaft (32);

when the column wheel (321) is matched with one of the oblique racks (31), the oblique rack (31) is positioned between two adjacent convex columns (3211), when the column wheel (321) moves along the plugging and unplugging direction, the convex columns (3211) slide along the oblique direction of the oblique rack (31) and rotate, and the convex columns (3211) rotate to drive the transmission shaft (32) to rotate;

when the previous convex column (3211) is separated from the previous helical rack (31), the adjacent next convex column (3211) is in contact with the adjacent next helical rack (31).

4. The launcher according to claim 1, wherein the transmission shaft (32) is a lead screw, the linkage part is a nut fixed on the sleeve (2), and the lead screw is in threaded fit with the nut;

when the sleeve (2) is plugged in and pulled out relative to the plug-in unit (1), the screw rod slides relative to the nut and rotates through threaded fit.

5. The launcher according to claim 1, wherein the transmission shaft (32) is provided with a spiral groove circumferentially arranged around the transmission shaft (32), and the linkage part is a lug arranged on the sleeve (2), and the lug is slidably connected in the spiral groove;

when the sleeve (2) is inserted into or pulled out of the plug-in unit (1), the lug slides along the spiral groove and drives the transmission shaft (32) to rotate.

6. The launcher according to claim 1, wherein the transmission shaft (32) is provided with a wave-shaped groove arranged around the circumference of the transmission shaft (32), and the linkage part is a lug arranged on the sleeve (2), and the lug is slidably connected in the wave-shaped groove;

when the sleeve (2) is plugged and pulled relative to the plug-in unit (1), the lug slides along the wave-shaped groove and drives the transmission shaft (32) to rotate.

7. The launcher according to claim 1, further comprising a stop assembly (13) for limiting disengagement of the rotating body from the rotational drive assembly (12), the stop assembly (13) being disposed on an insert (1).

8. The emitter according to claim 7, characterized in that said insert (1) comprises an emission opening (100);

when the rotating body is driven, the rotating body is limited in the transmitting opening (100) by the limiting assembly (13), and the rotating driving assembly (12) drives the rotating body to rotate;

when the launching device is used for launching, the limiting component (13) is unlocked, and the ejection component (11) drives the rotating body to be launched from the launching port (100).

9. The launcher according to any one of claims 1 to 8, wherein the rotary drive assembly (12) comprises an input gear (122) and a clutch gear (121), the input gear (122) is in transmission connection with the transmission shaft (32), the input gear (122) is in transmission connection with the clutch gear (121), the clutch gear (121) is movably arranged on the insert (1), and the rotating body is provided with a transmission gear;

when the plug-in (1) and the sleeve (2) are relatively pulled out, the clutch gear (121) is in transmission connection with the transmission gear;

when the plug-in (1) and the sleeve (2) are inserted relatively, the clutch gear (121) is separated from the transmission gear, and no transmission is performed between the clutch gear (121) and the transmission gear.

10. A top toy comprising a top and a launcher according to any one of claims 1 to 9.

Images