CN215195415U - Ejection toy - Google Patents

Abstract

The application discloses an ejection toy, which comprises a shell, an adsorption mechanism, an ejection mechanism and a trigger mechanism, wherein the adsorption mechanism is arranged in the shell and used for adsorbing an ejected object, and the trigger mechanism is linked with the ejection mechanism and used for triggering the ejection mechanism to act; the ejection toy has an adsorption state and an ejection state; when the ejection toy is in the adsorption state, the adsorption mechanism adsorbs the ejected object; when the ejection toy is in the ejection state, the trigger mechanism triggers the ejection mechanism to act, and the ejection mechanism ejects the ejected object. The utility model discloses can enough pop out the jettison thing, also can adsorb the jettison thing, can save the step of installation by the jettison thing, the method of playing is various moreover, can one play, also can two people play against each other, can also many people relay play, the object of playing reinforcing, interest and interactive height.

Description

Ejection toy

Technical Field

The application relates to the technical field of toys, in particular to an ejection toy.

Background

The ejection type toys are common in the market at present, the ejection toys can eject objects, the existing ejection toys can eject the ejected objects outwards and hit targets, and the ejection type toys are disclosed as follows: CN203235267U discloses an ejection toy, which comprises a shell and an ejection device, wherein the side surface of the shell is provided with a spring plate inlet, and the ejection device comprises a launching seat, a spring plate cylinder and a shooting mechanism; the launching seat is fixedly arranged at the bottom of the shell and is provided with an elastic sheet outlet; the pellet cylinder and the shooting mechanism are respectively arranged on the launching seat, and are both positioned in the shell; the spring sheet cylinder is vertically arranged, the upper end of the spring sheet cylinder is communicated with a spring sheet inlet on the side surface of the shell, and the lower end of the spring sheet cylinder is communicated with a spring sheet outlet on the launching seat; the side surface of the bottom of the pellet tube is provided with a shooting opening, and the shooting mechanism is positioned on the shooting opening on the side surface of the pellet tube.

The above-mentioned patent and the existing ejection toy often need manual loading when loading the thing that is ejected, and the thing that is ejected can only be popped out to current ejection toy, and can not catch the thing that is ejected, and the method of playing is single, and the interactivity is relatively poor, can't mobilize consumer's interest for a long time.

Therefore, a catapult toy with high playability and interactivity needs to be designed.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome prior art's not enough, provide a launch toy, can enough pop out the projectile, also can adsorb the projectile, can save the step of installation by the projectile, the method of playing is various moreover, can one play, also can two people fight and play, can also many people relay play, and the object of playing is strengthened, and is interesting and interactive high.

The playability is high, and the interactivity is strong.

The technical scheme of the application provides an ejection toy which comprises a shell, an adsorption mechanism, an ejection mechanism and a trigger mechanism, wherein the adsorption mechanism is arranged in the shell and used for adsorbing an ejected object, the trigger mechanism is linked with the ejection mechanism and used for triggering the ejection mechanism to act;

the ejection toy has an adsorption state and an ejection state;

when the ejection toy is in the adsorption state, the adsorption mechanism adsorbs the ejected object;

when the ejection toy is in the ejection state, the trigger mechanism triggers the ejection mechanism to act, and the ejection mechanism ejects the ejected object.

Preferably, the ejection mechanism comprises a natural state, an energy storage state and an energy release state, and the trigger mechanism has a first state and a second state which are triggered;

when the ejection toy is in the adsorption state, the ejection mechanism is in the natural state;

when the trigger mechanism is triggered to the first state, the ejection mechanism is driven to act, and the ejection mechanism is switched from the natural state to the energy storage state;

when the trigger mechanism further acts to the second state, the ejection mechanism is driven to be switched from the energy storage state to the energy release state, and the ejection mechanism ejects the ejected object.

Preferably, the ejection mechanism has an energy storage state and an energy release state;

when the ejection toy is in the adsorption state, the ejection mechanism is in the energy storage state;

when the ejection toy is in the ejection state, the ejection mechanism is switched from the energy storage state to the energy release state and ejects the ejected object.

Preferably, the ejection mechanism comprises a first sliding block and an elastic piece capable of driving the first sliding block, the first sliding block is connected with the shell in a sliding manner, and the trigger mechanism is connected with the first sliding block and can drive the first sliding block to act;

the first sliding block is provided with an initial position, a critical position and an ejection position;

when the first sliding block is at the initial position, the elastic piece is in the natural state;

when the first sliding block is in the critical position, the first sliding block enables the elastic piece to be in the energy storage state;

when the first sliding block is at the ejection position, the elastic piece is in the energy release state and ejects the first sliding block, and the first sliding block ejects the ejected object.

Preferably, the elastic piece is an elastic buckle, the elastic buckle comprises an opening, and a driving part is arranged at the end part of the first sliding block;

when the first sliding block is at the initial position, the driving part is separated from the elastic buckle;

when the first slide block is at the critical position, the driving part is positioned in the opening and props the opening open,

when the first sliding block is at the ejection position, the opening elastically contracts to enable the driving part to eject towards the direction far away from the opening.

Preferably, the device further comprises a linkage mechanism, the linkage mechanism comprises a rotating rod, the rotating rod is rotatably connected with the shell, one end of the rotating rod is connected with the triggering mechanism, and the other end of the rotating rod is connected with the first sliding block;

when the trigger mechanism is triggered, the trigger mechanism drives the rotating rod to rotate, and the rotating rod pushes the first sliding block to move towards the ejection direction.

Preferably, the trigger mechanism comprises a pressing part and a connecting rod, the connecting rod is connected with the pressing part, the connecting rod is rotatably connected with the shell, the connecting rod is linked with one end of the rotating rod, and the pressing part can drive the connecting rod to rotate;

when the pressing part is pressed, the connecting rod rotates and drives the rotating rod to rotate, and the rotating rod pushes the first sliding block to move.

Preferably, the linkage mechanism further comprises a second slider connected with the housing in a sliding manner, and the second slider is connected with the connecting rod;

the rotating rod comprises a first contact part and a second contact part, the first contact part and the second contact part are positioned on two sides of the rotating center of the rotating rod, and the first contact part is in contact with the first sliding block;

the second sliding block is provided with a third contact part and a fourth contact part, the connecting rod is in contact with the third contact part, and the fourth contact part is used for being in contact with the second contact part;

when the connecting rod pushes the second sliding block to slide, the fourth contact part drives the second contact part to rotate, so that the first contact part rotates and pushes the first sliding block to move towards the ejection direction.

Preferably, the elastic buckle is connected with the shell in a sliding manner through a mounting column, a first return spring is arranged between the elastic buckle and the shell, and a guide part for pushing the elastic buckle to slide along the axial direction of the mounting column is arranged at the end part of the second sliding block;

when the pressing part is pressed, the connecting rod rotates and pushes the second sliding block to slide to the elastic buckle, the guide part is in contact with the elastic buckle and pushes the elastic buckle to enable the first reset spring to be compressed, and the elastic buckle moves along the axial direction of the mounting column, so that the elastic buckle is connected with the first sliding block.

Preferably, the adsorption mechanism comprises an adsorption part for adsorbing the ejected object, a notch for accommodating the ejected object is arranged at the end part of the shell, and the adsorption part is arranged in the notch;

when the ejection toy is in the adsorption state, the ejected object is positioned in the notch and adsorbed by the adsorption part;

when the ejection toy is in the ejection state, the ejected object is ejected out of the notch.

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

the catapult toy can adsorb a catapult through the adsorption mechanism when playing, can eject the catapult through the catapult mechanism, can realize quick adsorption or catapult of the catapult, can save the step of installing the catapult compared with the existing catapult toy, has various playing methods, can be played by a single person, can also be played by two people in battle, can also be played by multiple persons in relay, has enhanced playability and high interestingness and interactivity.

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 structural view of a projectile toy according to an embodiment of the present invention;

fig. 2 is an exploded view of the ejection toy of the present invention in one embodiment;

fig. 3 is a schematic view of the ejection toy in an attached state with the base removed, according to an embodiment of the present invention;

fig. 4 is a schematic view of the ejector toy removal housing in one embodiment of the present invention;

fig. 5 is a schematic view of a linkage mechanism and trigger mechanism in one embodiment of the present invention;

fig. 6 is a schematic structural view of the elastic buckle according to an embodiment of the present invention;

fig. 7 is a schematic structural diagram of a second slider according to an embodiment of the present invention;

fig. 8 is a schematic view of the first slide in an initial position in one embodiment of the present invention;

fig. 9 is a schematic view of the first slide in a critical position in one embodiment of the invention;

fig. 10 is a schematic view of the first slide in an ejection position in accordance with an embodiment of the present invention.

Reference symbol comparison table:

a housing 1:

a base 11, a cover 12, a first return spring 13, a second return spring 14, and a third return spring 15;

the structure comprises a notch 100, a mounting column 101, a first rotating shaft 102, a second rotating shaft 103, a first slideway 104, a second slideway 105, a guide rail 106 and a groove 107;

the adsorption mechanism 2: an adsorption part 21;

the ejection mechanism 3:

the elastic buckle 31: cavity 310, opening 311, guide block 312;

first slider 32: a driving part 321, an impact tip 322, a guide slope 323;

the trigger mechanism 4:

a pressing portion 41 and a link 42;

the linkage mechanism 5:

the rotating rod 51: a first contact portion 511 and a second contact portion 512;

second slider 52: a third contact portion 521, a fourth contact portion 522, and a guide portion 523;

the object to be ejected 6.

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 is to be understood as belonging to the specific meanings in the present application as appropriate to the person of ordinary skill in the art.

The utility model discloses an ejection toy in some embodiments, as shown in fig. 1 and fig. 2, which comprises a shell 1, an adsorption mechanism 2 arranged in the shell 1 and used for adsorbing an object to be ejected 6, an ejection mechanism 3 and a trigger mechanism 4 linked with the ejection mechanism 3 and used for triggering the ejection mechanism 3 to act;

the ejection toy has an adsorption state and an ejection state;

when the ejection toy is in an adsorption state, the adsorption mechanism 2 adsorbs the ejected object 6;

when the ejection toy is in an ejection state, the trigger mechanism 4 triggers the ejection mechanism 3 to act, and the ejection mechanism 3 is ejected by the ejected object 6.

The device can be used for single-person play, double-person fighting play or multi-person play, a user drives the ejection mechanism 3 to act through the trigger mechanism 4, so that an ejected object 6 is ejected through the ejection mechanism 3, and the ejected object 6 is ejected through the ejection mechanism 3 again in a mode of being rebounded and being caught again by the ejected object 6 or in a mode of being caught by the ejected object 6 which can be ejected through the adsorption mechanism 2 by an opponent, so that the play method and interactivity of the ejection toy are improved. Meanwhile, the device can adsorb the ejected object 6 through the adsorption mechanism 2, so that the function of collecting the ejected object 6 is achieved, and the step of manually loading the ejected object 6 is omitted.

In some embodiments of the present invention, the ejection mechanism 3 has a natural state, an energy storage state and an energy release state, and the trigger mechanism 4 has a first state and a second state that are triggered;

when the ejection toy is in an adsorption state, the ejection mechanism 3 is in a natural state;

when the trigger mechanism 4 is triggered to the first state, the ejection mechanism 3 is driven to act, and the ejection mechanism 3 is switched to the energy storage state from the natural state;

when the trigger mechanism 4 further acts to the second state, the ejection mechanism 3 is driven to be switched from the energy storage state to the energy release state, and the ejection mechanism 3 ejects the ejected object 6.

In the suction state, the object 6 is sucked by the suction mechanism 2, and the ejection mechanism 3 is in a natural state, so that the object 6 can be held fixed to the suction mechanism 2. When the trigger mechanism 4 is triggered, the trigger mechanism 4 drives the ejection mechanism 3 to act and enables the ejection mechanism 3 to be switched from a natural state to an energy storage state, the trigger mechanism 4 continues to act and drives the ejection mechanism 3 to act, the ejection mechanism 3 is enabled to be switched from the energy storage state to an energy release state, and the ejection mechanism 3 releases energy and ejects an ejected object 6.

In some embodiments of the present invention, the ejection mechanism 3 has an energy storage state and an energy release state;

when the ejection toy is in an adsorption state, the ejection mechanism 3 is in an energy storage state;

when the ejection toy is in the ejection state, the ejection mechanism 3 is switched from the energy storage state to the energy release state and ejects the ejected object 6.

In the adsorption state, the ejected object 6 is adsorbed by the ejection mechanism 2, and the ejection mechanism 3 is in the energy storage state;

when the trigger mechanism 4 is triggered, the ejection mechanism 3 is driven to act, the ejection mechanism 3 is switched from the energy storage state to the energy release state, and the ejection mechanism 3 ejects the ejected object 6.

In some embodiments of the present invention, as shown in fig. 2, the ejection mechanism 3 includes a first slider 32 and an elastic member capable of driving the first slider 32 to move, the first slider 32 is slidably connected to the housing 1, and the trigger mechanism 4 is connected to the first slider 32 and is capable of driving the first slider 32 to move;

the first slider 32 has an initial position, a threshold position and an eject position.

When the first slider 32 is at the initial position, the elastic member is in a natural state;

when the first slide block 32 is in the critical position, the first slide block 32 enables the elastic element to be in an energy storage state;

when the first slide 32 is in the ejection position, the elastic member is in the release state and ejects the first slide 32, and the first slide 32 is ejected by the ejector 6.

As shown in fig. 3, a first slide 104 is provided in the housing 1, and the first slide 32 is engaged with the first slide, and an end of the first slide 32 close to the object 6 has a striking tip 322 capable of contacting the object 6.

As shown in fig. 8, when the ejection toy is in the attraction state, the first slider 32 is in the initial position, the striking tip 322 is in contact with the ejected object 6, the elastic member is in the natural state, and the elastic member is not in contact with the first slider 32 and does not apply a force to the first slider 32.

As shown in fig. 9, when the trigger mechanism 4 drives the first slider 32 to move toward the ejection direction, the trigger mechanism 4 drives the elastic member to contact with the first slider 32, and when the first slider 32 slides to a critical position, the first slider 32 makes the elastic member in an energy storage state.

As shown in fig. 10, the triggering mechanism 4 continues to drive the first slider 32 to move toward the ejection direction, so that the first slider 32 slides to the ejection position, at this time, the elastic member is in the energy release state, the elastic member elastically releases energy and ejects the first slider 32, the impact end 322 generates an impact force on the ejected object 6, and the impact force is at least greater than the adsorption force of the adsorption mechanism 2 on the ejected object 6, so that the ejected object 6 can be separated from the adsorption mechanism 2 and ejected.

In some embodiments of the present invention, as shown in fig. 6, the elastic member is an elastic buckle 31, the elastic buckle 31 includes an opening 311, and a driving portion 321 is disposed at an end of the first sliding block 32;

as shown in fig. 8, when the first slider 32 is at the initial position, the driving part 321 is separated from the elastic buckle 31;

as shown in fig. 9, when the first slider 32 is at the critical position, the driving portion 321 is in the opening 311 and spreads the opening 311;

as shown in fig. 10, when the first slider 32 is in the ejection position, the opening 311 elastically contracts to eject the driving portion 321 in a direction away from the opening 311.

The elastic buckle 31 further comprises a cavity 310, the opening 311 is communicated with the cavity 310, the cavity 310 is matched with the driving portion 321, one side of the opening 311, which is far away from the cavity 310, is provided with a guide block 312 which extends along one side of the elastic buckle 31, the two guide blocks 312 extend along the radial direction respectively, the driving portion 321 is in a round cake shape, the shape of the cavity 310 is the same as that of the driving portion 321, and the inner diameter of the cavity 310 is at least larger than or equal to the outer diameter of the driving portion 321. The distance between two points of the opening 311 in the radial direction is smaller than the outer diameter of the driving portion 321, and the distance between two points of the two guide blocks 312 in the radial direction gradually increases.

When the first slider 32 moves from the initial position to the critical position, that is, the driving portion 321 slides from the cavity 310 to the opening 311, and when the driving portion 321 passes through the opening 311, the maximum end diameter of the driving portion 321 is located in the opening 311, that is, the critical position, because the distance between two points of the opening 311 in the radial direction is smaller than the outer diameter of the driving portion 321, the opening 311 is radially expanded by the driving portion 321, and the elastic buckle 31 elastically deforms, and is in an energy storage state.

When the first slider 32 continues to move towards the ejection direction, and the maximum diameter end of the driving part 321 leaves the opening 311, the elastic buckle 31 contracts inwards under the action of the elastic force of the elastic buckle 31 and pushes the driving part 321 to eject towards the ejection direction, so that the elastic buckle 31 can provide a force for ejecting the ejected object 6 for the first slider 32, and the impact head 322 generates an impact force on the ejected object 6 to eject the ejected object 6. The guide block 312 can play a role of guiding when the first slider 32 is ejected, so that the ejection action of the first slider 32 is smoother. Or the first slider 32 can be guided by the guide block 312 to slide toward the elastic buckle 31 when being reset.

In some embodiments of the present invention, as shown in fig. 2-4, the present invention further includes a linkage mechanism 5, the linkage mechanism 5 includes a rotating rod 51, the rotating rod 51 is rotatably connected to the housing 1, one end of the rotating rod 51 is connected to the triggering mechanism 4, and the other end is connected to the first slider 32;

when the trigger mechanism 4 is triggered, the trigger mechanism 4 drives the rotating rod 51 to rotate, and the rotating rod 51 pushes the first slider 32 to move towards the ejection direction.

In some embodiments of the present invention, the trigger mechanism 4 includes a pressing portion 41 and a connecting rod 42, the connecting rod 42 is connected to the pressing portion 41, the connecting rod 42 is rotatably connected to the housing 1, the connecting rod 42 is linked to one end of the rotating rod 51, and the pressing portion 41 can drive the connecting rod 42 to rotate;

when the pressing portion 41 is pressed, the link 42 rotates and drives the rotating rod 51 to rotate, and the rotating rod 51 pushes the first slider 32 to move.

As shown in fig. 2, the housing 1 includes a base 11 and a cover 12 connected to the base 11, and an installation cavity for installing the adsorption mechanism 2 and the ejection mechanism 3 is formed between the base 11 and the cover 12.

Specifically, as shown in fig. 2 and 3, the link is rotatably connected in the housing 1 through a first rotating shaft 102, the rotating rod 51 is rotatably connected in the housing 1 through a second rotating shaft 103, the link 42 is integrally formed with the pressing portion 41, a guide rail 106 is further disposed in the housing 1, one end of the pressing portion 41 is connected with the first rotating shaft 102, the other end of the pressing portion 41 is slidably connected with the guide rail 106, an end of the pressing portion 41 can rotate around the first rotating shaft 102, the guide rail 106 is an arc-shaped rail matched with a movement track of the end of the pressing portion 41, at least a portion of the pressing portion 41 protrudes out of an outer wall surface of the housing 1, a user applies an inward acting force to the pressing portion 41, so that the pressing portion 41 can rotate inwards around the first rotating shaft 102, and the link 42 synchronously operates with the pressing portion 41, and the link 42 rotationally links the rotating rod 51.

In one embodiment of the present invention, the elastic buckle 31 is slidably connected to the housing 1 through the mounting post 101, and a first return spring 13 is disposed between the elastic buckle 31 and the housing 1. The linkage mechanism 5 further comprises a second slider 52 connected with the housing 1 in a sliding manner, the second slider 52 is connected with the connecting rod 42, and a guide portion 523 used for pushing the elastic buckle 31 to slide along the Z direction is arranged at the end of the second slider 52;

when the pressing portion 41 is pressed, the link 42 rotates and pushes the second slider 52 to slide toward the elastic buckle 31, the guide portion 523 contacts the elastic buckle 31 and pushes the elastic buckle 31 to move in the Z direction, so that the first return spring 13 is compressed, and the elastic buckle 31 slides in the axial direction of the mounting post 101, so that the elastic buckle 31 is connected with the first slider 32.

When the ejection toy is in the adsorption state, under the elastic force of the first return spring 13, the elastic buckle 31 and the first slider 32 are located in different Z-direction planes, that is, at this time, the elastic buckle 31 and the first slider 32 are separated along the Z-direction, and the driving portion 321 and the cavity 310 are arranged in a manner of overlapping along the Z-direction. When the object 6 to be ejected needs to be ejected, the pressing portion 41 is pressed and the second slider 52 is driven to slide downward along the Y direction, the guiding portion 523 at the end of the second slider 52 contacts the elastic buckle 31 and pushes the elastic buckle 31 to move along the Z direction, that is, the elastic buckle 31 slides toward the base 11 along the axial direction of the mounting post 101, so that the first slider 32 and the elastic buckle 31 are placed in the same plane, the driving portion 321 enters the cavity 310, and the pressing portion 41 is continuously pressed, so that the rotating rod 51 pushes the first slider 32 to slide toward the ejection direction, so that the first slider 32 moves from the initial position to the critical position, that is, the maximum end diameter of the driving portion 321 is placed in the opening, and at this time, the elastic buckle 31 is elastically deformed and is in the energy storage state. The pressing portion 41 is continuously pressed to drive the first slider 32 to move, so that the first slider 32 moves from the critical position to the ejection position, that is, the maximum end diameter of the driving portion 321 is separated from the opening, the elastic contraction of the opening 311 of the elastic buckle 31 releases energy, and a force for ejecting the object to be ejected 6 is applied to the first slider 32. Through setting up first reset spring 13 for elasticity is detained 31 and is in different Z to the plane with first slider 32 when adsorption state, and first slider 32 can not receive the backstop effect when reseing, can more smoothly reset fast, so that carry out the ejection next time.

In one embodiment of the present invention, as shown in fig. 4, the rotating rod 51 includes a first contacting portion 511 and a second contacting portion 512, the first contacting portion 511 and the second contacting portion 512 are located at two sides of the rotation center of the rotating rod 51, and the first contacting portion 511 is in contact with the first slider 32;

as shown in fig. 7, the second slider 52 has a third contacting portion 521 and a fourth contacting portion 522, as shown in fig. 5, the link 42 contacts with the third contacting portion 521, and the fourth contacting portion 522 is used for contacting with the second contacting portion 512;

when the connecting rod 42 pushes the second slider 52 to slide downward, the fourth contacting portion 522 drives the second contacting portion 512 to rotate, so that the first contacting portion 511 rotates and pushes the first slider 32 to move toward the ejection direction.

Be provided with the second slide 105 with second slider 52 assorted in casing 1, first slide 104 and second slide 105 are located the equidirectional, be provided with first portion 511 and the second portion 512 of touching respectively in the rotation center both sides that rotary rod 51 is connected with second axis of rotation 103, wherein be equipped with direction inclined plane 323 on first slider 32, first portion 511 and the contact of direction inclined plane 323 of touching, second portion 512 and connecting rod 42 of touching are in respectively between third portion 521 and the fourth portion 522 of touching, the upper end of second portion 512 of touching can touch the lower extreme contact of portion 522 with the fourth portion 522 of touching, the tip of connecting rod 42 can touch the upper end contact of portion 521 with the third portion of touching. When the user presses the pressing portion 41 inward, the link 42 rotates and presses the second slider 52 downward, the second slider 52 slides downward, and at the same time, the fourth contacting portion 522 on the second slider 52 moves downward and pushes the second contacting portion 512 of the rotating rod 51 to move downward, so that the first contacting portion 511 at the other end of the rotating rod 51 moves upward and pushes the first slider 32 to slide upward, so that the first slider 32 can be switched from the initial position to the critical position and then to the ejection position.

Optionally, the elastic buckle 31 is fixedly connected to the housing 1, that is, the elastic buckle 31 is fixed in the Z direction, when the first slider 32 is at the initial position, the driving portion 321 is disposed in the cavity 310, at this time, the elastic buckle 31 is in a natural state, there is no interaction force between the elastic buckle 31 and the driving portion 321, the pressing portion 41 is pressed to drive the first slider 32 to slide along the ejection direction, so that the first slider 32 moves from the initial position to the critical position, that is, the driving portion 321 slides along the Y direction from the cavity to the opening, and when the maximum end diameter of the driving portion 321 is disposed in the opening, the critical position is defined as the critical position, at this time, the elastic buckle 31 generates elastic deformation and is in the energy storage state. The pressing portion 41 is continuously pressed to drive the first slider 32 to continuously slide along the ejection direction, so that the first slider 32 moves from the critical position to the ejection position, that is, the maximum end diameter of the driving portion 321 is separated from the opening, the elastic contraction of the opening 311 of the elastic buckle 31 releases energy, and a force for ejecting the object to be ejected 6 is applied to the first slider 32.

When the ejected object 6 is loaded, the ejected object 6 pushes the driving part 321 in the first slider 32 to slide toward the cavity 310 along the Y direction, when the driving part 321 passes through the opening, the driving part 321 opens the opening and enters the cavity 310, when the driving part 321 completely enters the cavity 310, the elastic buckle 31 elastically resets and is in a natural state, and no interaction force acts between the elastic buckle 31 and the driving part 321. Meanwhile, when the first sliding block 32 acts, the first sliding block 32 drives the rotating rod 51 to rotate, and the rotating rod 51 drives the connecting rod 42 to rotate, so that the pressing part 41 slides outwards along the guide rail 106 to the initial position, and the resetting is completed, thereby preparing for the next ejection. In some embodiments of the present invention, the present invention further comprises a second return spring 14, and the second return spring 14 is respectively connected to the second slider 52 and the housing 1;

when the urging force of the pressing portion 41 is cancelled, the second return spring 14 is returned and pushes the pressing portion 41 to be returned.

When the acting force of the pressing portion 41 is removed, the second return spring 14 returns and pushes the second slider 52 to slide upward, the second slider 52 rotates the link rod 42, and the pressing portion 41 is caused to slide outward along the guide rail 106 to return. The pressing part 41 can be automatically reset through the second return spring 14, and after the external force is removed, the pressing part 41 slides outwards to reset under the elastic force of the second return spring 14, so that the user can use the ejection device for the next time.

In some embodiments of the present invention, the present invention further comprises a third return spring 15, and the third return spring 15 is respectively connected to the first sliding block 32 and the housing 1;

when the urging force of the pressing portion 41 is cancelled, the third return spring 15 is returned and pushes the first slider 32 to be returned to the initial position.

When the acting force of the pressing portion 41 is removed, the third return spring 15 returns to the original position and pushes the first slider 32 to slide towards the elastic buckle 31, and meanwhile, due to the separation of the second slider 52 and the elastic buckle 31, the elastic buckle 31 slides away from the base 11 along the axial direction of the mounting post 101 under the elastic force of the first return spring 13, so that the elastic buckle 31 and the first slider 32 are located on different planes, and the third return spring 15 can push the first slider 32 to slide to the initial position, that is, the driving portion 321 of the first slider 32 is disposed between the base 11 and the elastic buckle 31. The first sliding block 32 can be automatically reset by arranging the third return spring 15, and when the acting force of the pressing part 41 is cancelled by a user, the first sliding block 32 automatically resets under the action of the elastic force of the third return spring 15, so that the next ejection use can be facilitated.

In some embodiments of the present invention, the adsorption mechanism 2 includes an adsorption part 21 for adsorbing the object to be ejected 6, the end of the housing 1 is provided with a notch 100 for accommodating the object to be ejected 6, and the adsorption part 21 is disposed in the notch 100.

As shown in fig. 8, when the ejection toy is in the suction state, the object to be ejected 6 is in the notch 100 and is sucked and fixed by the suction part 21;

when the ejector toy is in the ejection state, the object 6 is ejected out of the recess 100.

At the bottom of the recess 100, a through hole is provided through which the end of the first slider 32 can pass to contact the object 6 to be ejected accommodated in the recess 100. When the ejection toy is in the ejection state, the elastic piece pushes the first slide block 32 to slide towards the notch 100, and the end part of the first slide block 32 penetrates through the communication hole and contacts with the ejected object 6, so that the ejected object 6 is ejected out of the notch 100. The impact force applied to the ejection target 6 by the first slider 32 needs to be larger than the suction force of the suction portion 21 to the ejection target 6.

In some embodiments of the present invention, the absorption portion 21 is a magnet, the recess 107 for installing the magnet is provided in the bottom of the recess 100 and is recessed inwards, the recess 100 is circular-arc matched with the circumferential profile of the ejected object 6, the ejected object 6 is in a circular cake shape, and at least part of the ejected object 6 is in an iron structure capable of being absorbed by the magnet. In the attracted state, when the object 6 is loaded into the recess 100, the magnet provided at the bottom of the recess 100 attracts and fixes the object 6 in the recess 100. The attraction part 21 is made of a magnet, so that when the object 6 is near the notch 100, the object 6 can be attracted into the notch 100 by the attraction of the magnetic force, and the user can more easily catch the object 6.

Alternatively, the suction unit 21 may be a hook and loop fastener, and a lint that can be attached to the hook and loop fastener may be provided on the ejection target 6.

Alternatively, the suction portion 21 can be an adhesive, and the ejectors 6 can be adhesively fixed in the recesses 100 by the adhesive when the ejectors 6 are loaded in the recesses 100.

Optionally, the ejection mechanism 3 can also be a second slider 52 and a second return spring 14, wherein in this optional embodiment, the second slider 52 is connected to the first slider 32, the second slider 52 moves synchronously with the first slider 32, the aperture of the opening 311 of the elastic buckle 31 is larger than the maximum end diameter of the driving portion 321 on the first slider 32, in the adsorption state, the elastic buckle 31 is placed in the cavity 310, and the pressing portion 41 presses inward, the link rod 42 pushes the second slider 52 to slide downward, and the second return spring 14 compresses. In the ejection state, the acting force of the pressing part 41 is removed, at this time, the second return spring 14 is reset and pushes the second slide block 52 to slide upwards, and the second slide block 52 drives the first slide block 32 to slide upwards, so that the ejected object 6 is ejected.

Example 1:

the embodiment discloses an ejection toy, which is used for ejecting or adsorbing an ejected object 6, and as shown in fig. 1 and 2, the ejection toy comprises a shell 1, an ejection mechanism 3, an adsorption mechanism 2 and a trigger mechanism 4, wherein in the embodiment, the width direction of the shell 1 is defined as an X direction, the length direction of the shell 1 is defined as a Y direction, and the height direction of the shell 1 is defined as a Z direction.

In the present embodiment, the housing 1 includes a base 11 and a cover 12, the base 11 and the cover 12 are connected to form a mounting cavity, wherein, as shown in fig. 1 and 2, the suction mechanism 2 is disposed at the front end of the housing 1 in the Y direction, specifically, the suction mechanism 2 includes a suction portion 21, a notch 100 is formed at the front end of the housing 1 in the Y direction, the suction portion 21 is disposed in the notch 100, the contour shape of the notch 100 matches the ejected object 6, the ejected object 6 can be at least partially fitted into the notch 100, and the ejected object 6 can be sucked by the suction portion 21 disposed in the notch 100, so that the ejected object 6 cannot be detached from the notch 100.

Specifically, in the present embodiment, the object to be ejected 6 is a disk-shaped structure, the recess 100 is an arc shape matching with the circumferential contour of the object to be ejected 6, the adsorption portion 21 is a magnet, at least a part of the object to be ejected 6 is an iron structure capable of adsorbing the magnet, a groove 107 is recessed inward at the bottom of the recess 100, the magnet is installed and fixed in the groove 107, and when the object to be ejected 6 is loaded into the recess 100, the magnet placed at the bottom of the recess 100 can adsorb the object to be ejected 6 so that it will not fall off the recess 100 without external force.

Alternatively, the suction part 21 may be a hook and loop fastener, and a lint is provided on the circumferential surface of the ejected object 6, and the hook and loop fastener adheres the lint on the surface of the ejected object 6 when the ejected object 6 is inserted into the recess 100. The suction portion 21 can be made of an adhesive, and the ejectors 6 can be fixed to the notches 100 by adhering the ejectors 6 to the notches 100 when the ejectors 6 are loaded into the notches.

In the present embodiment, as shown in fig. 2 to 4, the ejection mechanism 3 includes a first slider 32 slidably disposed in the housing 1, and an elastic member, wherein a first slide 104 disposed along the Y direction is disposed in the housing 1, the first slider 32 is slidably disposed in the first slide 104, one end of the first slider 32 near the notch has an impact tip 322, the other end has a driving portion 321, a communication hole is disposed at the bottom of the notch 100, and the impact tip 322 can enter the notch 100 through the communication hole and contact the object to be ejected 6 mounted in the notch 100.

In the present embodiment, as shown in fig. 2 to 4, the elastic member is an elastic buckle 31, the elastic buckle 31 is fixedly installed in the housing 1, wherein as shown in fig. 5, the elastic buckle 31 includes a cavity 310 matching with the driving portion 321 and an opening 311 communicating with the cavity 310, and the elastic buckle 31 is made of an elastic material, wherein as shown in fig. 5, the driving portion 321 on the first slider 32 is in a pie shape, the cavity 310 has the same shape as the driving portion 321, and an inner diameter of the cavity 310 is greater than or equal to an outer diameter of the driving portion 321, so that the driving portion 321 can be accommodated in the cavity 310. The distance between two points of the opening 311 in the radial direction is smaller than the maximum end diameter of the driving part 321, two guide blocks 312 are symmetrically arranged on one side of the opening 311 away from the cavity 310, and the distance between two points of the two guide blocks 312 in the radial direction gradually increases.

In the present embodiment, as shown in fig. 2, the trigger mechanism 4 is linked with the ejection mechanism 3 through a linkage mechanism 5, specifically, the trigger mechanism 4 includes a pressing portion 41 and a connecting rod 42, the linkage mechanism 5 includes a second slider 52 and a rotating rod 51, wherein openings for extending the pressing portion 41 are provided on two sides of the housing 1, at least a portion of the pressing portion 41 extends from the openings to the outside of the housing 1, the two pressing portions 41 are symmetrically provided on two sides of the housing 1, respectively, wherein the pressing portion 41 and the connecting rod 42 are integrally formed, the connecting portion of the connecting rod 42 and the pressing portion 41 is rotatably connected with the housing 1 through a first rotating shaft 102, the first rotating shaft 103 is arranged along the Z direction, a guide rail 106 is further provided in the housing 1, one end of the pressing portion 41 is rotatably connected with the first rotating shaft 102, the other end is provided with a guide post, the guide post is located in the guide rail 106 and can slide along the guide rail 106, the end of the pressing portion 41 is rotatable about the first rotation axis 102, and the guide rail 106 is an arc-shaped rail that matches the movement locus of the end of the pressing portion 41.

Optionally, the outer side surface of the pressing portion 41 is provided with anti-slip lines for increasing the hand feeling of holding and increasing the friction force with the human hand.

As shown in fig. 2 to 4, two second sliders 52 and a rotating rod 51 are symmetrically disposed in the housing 1, wherein a second slide 105 disposed along the Y direction is disposed in the housing 1, the second slider 52 is slidably disposed on the second slide 105, the rotating rod 51 is rotatably connected to the housing 1 through a second rotating shaft 103, the second rotating shaft 103 is disposed along the Z direction, a first contact portion 511 and a second contact portion 512 are disposed on two sides of a rotating center where the rotating rod 51 is connected to the second rotating shaft 103, a guiding inclined surface 323 is disposed on the first sliding seat, and the first contact portion 511 is in contact with the guiding inclined surface 323.

As shown in fig. 4 and 6, the second slider 52 is provided with a third contacting portion 521 and a fourth contacting portion 522, the second contacting portion 512 and the connecting rod 42 are respectively located between the third contacting portion 521 and the fourth contacting portion 522, the upper end of the second contacting portion 512 can contact with the lower end of the fourth contacting portion 522, and the end of the connecting rod 42 can contact with the upper end of the third contacting portion 521. When the pressing portion 41 is pressed inward, the pressing portion 41 slides inward along the guide rail 106 and drives the connecting rod 42 to rotate downward, the end portion of the connecting rod 42 contacts with the third contacting portion 521 and pushes the second slider 52 to slide downward along the Y direction, meanwhile, the fourth contacting portion 522 slides downward, the fourth contacting portion 522 contacts with the upper end of the second contacting portion 512 and drives the second contacting portion 512 to move downward, and because the first contacting portion 511 and the second contacting portion 512 are respectively located at two sides of the rotation center of the rotating rod 51, the second contacting portion 512 moves downward along the Y direction and simultaneously the first contacting portion 511 moves upward along the Y direction, so that the first slider 32 is pushed by the first contacting portion 511 to move upward along the Y direction, and the position of the first slider 32 is changed.

In this embodiment, as shown in fig. 3, a second return spring 14 and a third return spring 15 are further included, wherein a containing groove for containing the second return spring 14 is provided in the housing 1, one end of the second return spring 14 is connected to the first slider 32, and the other end is connected to an inner wall of the containing groove. One end of the third return spring 15 is connected to the second slider 52, and the other end is connected to the inner wall of the housing 1.

The ejection toy comprises an adsorption state and an ejection state;

as shown in fig. 8, when the ejection toy is in the adsorption state, the first slider 32 is in the initial position, that is, the ejected object 6 is loaded into the notch 100 at this time, the ejected object 6 pushes the first slider 32 to slide downward along the Y direction, so that the driving portion 321 on the first slider 32 expands the opening 311 of the elastic buckle 31 and finally locates in the cavity 310, and at this time, the elastic buckle 31 is in the natural state, and the elastic buckle 31 does not apply a force to the driving portion 321. In the adsorption state, the ejected object 6 is adsorbed by the magnet in the recess 100 and cannot be separated, and at this time, the second return spring 14 and the third return spring 15 are in the extension state, the pressing part 41 is located at one end of the guide rail 106 close to the side wall of the housing 1, and when no external force is applied, the ejected object 6 is adsorbed by the magnet in the recess 100 and cannot be separated.

In the ejection state, a user presses the pressing portion 41 inward, the pressing portion 41 slides from one end of the guide rail 106 close to the side wall to one end of the guide rail far from the side wall, and drives the connecting rod 42 to rotate, the end portion of the connecting rod 42 moves downward along the Y direction and pushes the second slider 52 to slide downward along the Y direction, and simultaneously drives the fourth contacting portion 522 to move downward along the Y direction, the fourth contacting portion 522 drives the second contacting portion 512 to move and makes the first contacting portion 511 move upward along the Y direction, the first contacting portion 511 pushes the first slider 32 to slide along the ejection direction, so that the driving portion 321 on the first slider 32 slides along the opening 311 direction, as shown in fig. 9, when the maximum end diameter of the driving portion 321 is located at the opening 311, the first slider 32 is located at a critical position, the driving portion 321 props up the opening 311, and the elastic buckle 31 elastically deforms, and is located in the energy storage state. As shown in fig. 10, when the maximum end diameter of the driving portion 321 is separated from the opening 311, the first slider 32 is at the ejection position, and at this time, an elastic force applied to the first slider 32 in the ejection direction under the elastic contraction action of the opening 311 of the elastic buckle 31 causes the first slider 32 to slide in the ejection direction, the impact tip 322 of the first slider 32 contacts with the object 6 to be ejected and transmits the ejection force to the object 6 to be ejected, and the ejection force is greater than the attraction force between the magnet and the object 6 to be ejected, so that the object 6 to be ejected can be ejected.

When the user cancels the pressing force of the pressing portion 41, the third return spring 15 is reset and pushes the first slider 32 to slide downward along the Y direction, so that the driving portion 321 of the first slider 32 can open the opening 311 and enter the cavity 310 again, and the first slider 32 is reset to the initial position, that is, the first slider 32 is placed in the cavity 310. The second return spring 14 returns to push the second slider 52 to slide upwards along the Y direction, and the second slider 52 drives the link rod 42 to rotate upwards and drives the pressing portion 41 to slide from the inner end to the outer end of the guide rail 106 to prepare for the next ejection. The driving portion 321 is guided by the guiding block 312 on the opening 311 from the outside of the opening 311 into the cavity 310.

The toy can be played by a single person, the ejected object 6 is ejected to the wall, the ejected object 6 rebounds back through the wall, and a player catches the toy and can launch the next time. Or the player aims at the shot object and then launches the shot object 6, and plays with the aim of shooting the shot object.

The toy can also be played by two persons for fighting, wherein one user presses the pressing part 41 to eject the ejected object 6, and the other user presses the pressing part 41 to eject the ejected object 6.

The toy can also be played by a plurality of people, the ejectors 6 are ejected and caught in a relay mode by the plurality of people, for example, the first player ejects the ejectors 6 and is caught by the second player, the second player ejects the ejectors 6 and is caught by the third player, and the third player ejects the ejectors 6 and is caught by the first player, so that the process is repeated.

Therefore, the toy has various playing methods, and the playing method and interactivity of the ejection toy can be increased. Meanwhile, the toy can adsorb the ejected object through the adsorption mechanism 2, and the step of installing the ejected object can be omitted.

Example 2:

this embodiment is similar to embodiment 1, except that in this embodiment, as shown in fig. 2 and 4, the elastic buckle 31 is connected to the housing 1 through a mounting post 101, wherein the mounting post 101 is disposed along the Z direction, the elastic buckle 31 can slide up and down along the mounting post 101, a first return spring 13 is disposed between the housing 1 and the elastic buckle 31, one end of the first return spring 13 contacts with the bottom surface of the elastic buckle 31, and the other end contacts with the housing 1.

In this embodiment, a guide portion 523 is disposed at one end of the second slider 52 close to the elastic buckle 31, when the second slider 52 slides downward in the Y direction, the guide portion 523 contacts the elastic buckle 31 and pushes the elastic buckle 31 to slide downward in the Z direction, so that the first return spring 13 is compressed, and when the guide portion 523 is separated from the elastic buckle 31, the first return spring 13 is reset and pushes the elastic buckle 31 to slide upward in the Z direction.

In this embodiment, when the ejection toy is in the attraction state, under the elastic force of the first return spring 13, the elastic fastener 31 and the first slider 32 are located in different planes in the Z direction, at this time, the elastic fastener 31 is separated from the first slider 32, and the driving portion 321 is located below the cavity 310. When the object to be ejected 6 needs to be ejected, the pressing portion 41 is pressed and the second slider 52 is driven to slide downward along the Y direction, the guide portion 523 at the end of the second slider 52 contacts the elastic buckle 31 and pushes the elastic buckle 31 to slide downward along the Z direction, so that the elastic buckle 31 moves to be located on the same plane as the first slider 32 in the Z direction, the driving portion 321 enters the cavity 310 along the Z direction, the pressing portion 41 is continuously pressed, the rotating rod 51 pushes the first slider 32 to slide toward the ejection direction, and finally, an acting force for ejecting the object to be ejected 6 is applied to the first slider 32 under the elastic contraction action of the opening 311 of the elastic buckle 31.

When the user cancels the acting force applied to the pressing part 41, the second return spring 14 is reset and separates the second slider 52 from the elastic buckle 31, the elastic buckle 31 slides upwards along the Z direction under the elastic force of the first return spring 13 to separate the first slider 32 from the elastic buckle 31 along the Z direction, the first slider 32 slides back to the initial position along the Y direction under the reset acting force of the third return spring 15, at this time, because the first slider 32 and the elastic buckle 31 are located on different planes, and the driving part 321 and the cavity 310 are overlapped along the Z direction, the opening 311 does not need to be opened by the first slider 32 in the resetting process, so that the resetting is smoother.

Example 3:

the present embodiment is similar to embodiment 1, except that in the present embodiment, the ejection mechanism 3 includes a first slider 32, a second slider 52 and a second return spring 14, wherein in the present embodiment, the first slider 32 and the second slider 52 are fixedly connected and move synchronously, the elastic buckle 31 is fixedly installed in the housing 1 and located in the same plane in the Z direction as the first slider 32, and the aperture of the opening 311 of the elastic buckle 31 is larger than the maximum end diameter of the driving portion 321.

In the suction state, the user presses the pressing portion 41 so that the pressing portion 41 is located at the inner end of the guide rail 106, and the second return spring 14 is in the compressed state, and the ejectors 6 are loaded into the notches 100.

In the ejection state, when the user releases the pressing portion 41, after the second return spring 14 returns and pushes the second slider 52 to slide upward in the Y direction, the second slider 52 drives the first slider 32 to slide upward in the Y direction, so that the striking tip 322 at the end of the first slider 32 applies an ejection force to the object 6 to eject the object 6 out of the notch 100. In this embodiment, the third return spring 15 is not required, and the user may press the pressing part 41 when he or she needs to return the ejection toy to the suction state.

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. An ejection toy is characterized by comprising a shell (1), an adsorption mechanism (2) which is arranged in the shell (1) and is used for adsorbing an ejected object (6), an ejection mechanism (3) and a trigger mechanism (4) which is linked with the ejection mechanism (3) and is used for triggering the ejection mechanism (3) to act;

the ejection toy has an adsorption state and an ejection state;

when the ejection toy is in the adsorption state, the adsorption mechanism (2) adsorbs the ejected object (6);

when the ejection toy is in the ejection state, the trigger mechanism (4) triggers the ejection mechanism (3) to act, and the ejection mechanism (3) ejects the ejected object (6).

2. The ejection toy of claim 1,

the ejection mechanism (3) has a natural state, an energy storage state and an energy release state, and the trigger mechanism has a triggered first state and a triggered second state;

when the ejection toy is in the adsorption state, the ejection mechanism (3) is in the natural state;

when the trigger mechanism (4) is triggered to the first state, the ejection mechanism (3) is driven to act, and the ejection mechanism (3) is switched to the energy storage state from the natural state;

when the trigger mechanism (4) further acts to the second state, the ejection mechanism (3) is driven to be switched from the energy storage state to the energy release state, and the ejected object (6) is ejected by the ejection mechanism (3).

3. The ejection toy of claim 1,

the ejection mechanism (3) has an energy storage state and an energy release state;

when the ejection toy is in the adsorption state, the ejection mechanism (3) is in the energy storage state;

when the ejection toy is in the ejection state, the ejection mechanism (3) is switched from the energy storage state to the energy release state and ejects the ejected object (6).

4. The ejection toy of claim 2, wherein the ejection mechanism (3) comprises a first slider (32) and an elastic element capable of driving the first slider (32), the first slider (32) is slidably connected with the housing (1), and the trigger mechanism (4) is connected with the first slider (32) and is capable of driving the first slider (32) to move;

the first slide (32) having an initial position, a threshold position and an ejection position;

when the first slider (32) is in the initial position, the elastic element is in the natural state;

when the first slider (32) is in the critical position, the first slider (32) enables the elastic element to be in the energy storage state;

when the first sliding block (32) is at the ejection position, the elastic piece is in the energy release state and ejects the first sliding block (32), and the first sliding block (32) ejects the ejected object (6).

5. The ejection toy of claim 4, wherein the elastic member is an elastic buckle (31), the elastic buckle (31) comprises an opening (311), and the end of the first slider (32) is provided with a driving part (321);

when the first slider (32) is in the initial position, the driving part (321) is separated from the elastic buckle (31);

when the first slider (32) is in the critical position, the driving portion (321) is in the opening (311) and spreads the opening (311) open;

when the first slider (32) is at the ejection position, the opening (311) elastically contracts to eject the driving part (321) in a direction away from the opening (311).

6. The ejection toy of claim 4, further comprising a linkage mechanism (5), wherein the linkage mechanism (5) comprises a rotating rod (51), wherein the rotating rod (51) is rotatably connected with the housing (1), and one end of the rotating rod (51) is connected with the trigger mechanism (4) and the other end is connected with the first slider (32);

when the trigger mechanism (4) is triggered, the trigger mechanism (4) drives the rotating rod (51) to rotate, and the rotating rod (51) pushes the first sliding block (32) to move towards the ejection direction.

7. The ejection toy of claim 6, wherein the trigger mechanism (4) comprises a pressing portion (41) and a connecting rod (42), the connecting rod (42) is connected with the pressing portion (41), the connecting rod (42) is rotatably connected with the housing (1), the connecting rod (42) is linked with one end of the rotating rod (51), and the pressing portion (41) can drive the connecting rod (42) to rotate;

when the pressing part (41) is pressed, the connecting rod (42) rotates and drives the rotating rod (51) to rotate, and the rotating rod (51) pushes the first sliding block (32) to move.

8. The ejection toy of claim 7, wherein the linkage mechanism (5) further comprises a second slider (52) slidably connected to the housing (1), the second slider (52) being connected to the link (42);

the rotating rod (51) comprises a first contact part (511) and a second contact part (512), the first contact part (511) and the second contact part (512) are positioned on two sides of the rotating center of the rotating rod (51), and the first contact part (511) is in contact with the first sliding block (32);

the second sliding block (52) is provided with a third contact part (521) and a fourth contact part (522), the connecting rod (42) is in contact with the third contact part (521), and the fourth contact part (522) is used for being in contact with the second contact part (512);

when the connecting rod (42) pushes the second sliding block (52) to slide, the fourth contact part (522) drives the second contact part (512) to rotate, so that the first contact part (511) rotates and pushes the first sliding block (32) to move towards the ejection direction.

9. The ejection toy of claim 4, wherein the elastic buckle (31) is slidably connected with the housing (1) through a mounting column (101), a first return spring (13) is arranged between the elastic buckle (31) and the housing (1), and a guide part (523) for pushing the elastic buckle (31) to slide along the axial direction of the mounting column (101) is arranged at the end part of the second sliding block (52);

when the pressing part (41) is pressed, the connecting rod (42) rotates and pushes the second sliding block (52) to slide to the elastic buckle (31), the guide part (523) is in contact with the elastic buckle (31) and pushes the elastic buckle (31) to compress the first return spring (13), and the elastic buckle (31) moves along the axial direction of the mounting column (101) to enable the elastic buckle (31) to be connected with the first sliding block (32).

10. The ejection toy according to any one of claims 1 to 9, wherein the suction mechanism (2) comprises a suction portion (21) for sucking the ejectors (6), the end of the housing (1) is provided with a recess (100) for accommodating the ejectors (6), and the suction portion (21) is disposed in the recess (100);

when the ejection toy is in the adsorption state, the ejected object (6) is in the notch (100) and is adsorbed by the adsorption part (21);

when the ejection toy is in the ejection state, the ejected object (6) is ejected out of the notch (100).

Images