CN111450544A - Linkage soaring push shooting toy - Google Patents

Abstract

The invention discloses a linkage soaring and propelling toy, which comprises: the first toy comprises a walking mechanism, a linkage mechanism, an emptying mechanism and a pushing mechanism, the linkage mechanism combines the second toy with the first toy when the first toy walks to the second toy, the emptying mechanism is triggered to unlock after combination so that the first toy drives the second toy to empty, the pushing mechanism is triggered to unlock after the first toy is empty, and the pushing mechanism drives the second toy to break away from the linkage mechanism and shoot away from the first toy after the pushing mechanism is unlocked. According to the linked soaring and pushing toy disclosed by the embodiment of the invention, the first toy can be automatically combined with the second toy in the walking process, the second toy can be driven to soar together, and the second toy can be launched out after the second toy soars.

Description

Linkage soaring push shooting toy

Technical Field

The invention relates to the field of toys, in particular to a linkage soaring and propelling toy.

Background

The existing linkage toys are of few types. The toy has the advantages of simple linkage toy, single linkage action and low interestingness. For example, two toys can be combined and deformed after being collided; for example, one toy is deformed after entering another toy, and another launching object is launched after the deformation. The other type of linked toy can complete all actions only by manual operation, for example, a large toy clamps another small toy and then deforms, and the small toy is shot out by manually pressing a button on the large toy. The manual-operated linkage toy of the type can not embody the continuity of the toy in action, and is difficult to arouse the excitement and fun of the player.

Disclosure of Invention

The present invention is directed to solving at least one of the problems of the prior art. Therefore, the invention provides a linkage soaring and pushing toy which can automatically complete all linkage actions and has complex actions and strong interestingness.

A linkage flight propelling toy according to an embodiment of the present invention includes: the toy comprises a first toy and a second toy, wherein the first toy comprises a walking mechanism, a linkage mechanism, an emptying mechanism and a pushing mechanism, the linkage mechanism combines the second toy with the first toy when the first toy walks to the second toy, the emptying mechanism is triggered to unlock after combination so that the first toy drives the second toy to empty, the pushing mechanism is triggered to unlock after the first toy is empty, and the pushing mechanism drives the second toy to break away from the linkage mechanism and shoot away from the first toy after the pushing mechanism is unlocked.

According to the linked soaring and pushing toy disclosed by the embodiment of the invention, the first toy can be automatically combined with the second toy in the walking process, the second toy can be driven to soar together, and the second toy can be launched out after the second toy soars.

In some embodiments, the first toy further comprises: a deformation mechanism, the deformation mechanism comprising: a deforming member, the deforming member being retractably provided on the first toy; the deformation lock catch is arranged on the first toy in a sliding mode and is configured to slide towards a position matched with the deformation piece normally so as to lock the deformation piece; and the ejection mechanism triggers the deformed lock catch to unlock when driving the second toy to be disengaged.

In some embodiments, the ejection mechanism comprises: a projectile for ejecting the second toy away from the first toy; the ejection locking piece is multiple, multiple ejection locking pieces form multiple sealing of the ejection pieces, and one of the ejection locking pieces is unlocked when the emptying mechanism acts.

Specifically, one of the push-fire locks is provided at a bottom of the first toy and is configured to be unlocked by impact when the first toy is airborne.

Furthermore, the emptying mechanism comprises a turning plate which is rotatably arranged at the bottom of the first toy, the turning plate is provided with a turning plate locking position and a turning plate unlocking position, and the turning plate is rotated to the turning plate unlocking position from the turning plate locking position when the emptying mechanism is unlocked; the push-shooting locking piece comprises a push-shooting first locking piece, when the turning plate is located at the position where the turning plate is locked, the push-shooting first locking piece is locked on the push-shooting piece, and when the turning plate is located at the position where the turning plate is unlocked, the turning plate pushes the push-shooting first locking piece to be unlocked.

Optionally, the push-shooting locking piece comprises a push-shooting second locking piece, the turning plate restricts the push-shooting second locking piece when the turning plate is locked in position, the turning plate is unlocked when the turning plate leaves the turning plate and locked in position, so that the push-shooting second locking piece is locked on the push-shooting piece, and the ground impacts the push-shooting second locking piece to unlock the first toy when the first toy is empty and falls to the ground.

Furthermore, the ejection second locking piece is rotatably connected to the first toy, the ejection second locking piece has a locking hook end and an unlocking end around a rotating shaft of the ejection second locking piece, the locking hook end is used for hooking the ejection second locking piece, and when the locking hook end is hooked on the ejection second locking piece, a part of the unlocking end is positioned below the bottommost end of the walking mechanism; when the turning plate is positioned at the turning plate locking position, the turning plate is pressed against the push-shooting second locking piece, and the unlocking end is positioned above the bottommost end of the travelling mechanism.

Optionally, a back projection is formed on the unlocking end, and when the turning plate is pressed against the push-shooting second locking piece, the back projection is clamped on the push-shooting piece.

In some embodiments, the linkage mechanism comprises: a grip and/or a suction for engaging the second toy; the linkage rod is movably arranged in the first toy, the linkage rod is matched with the emptying mechanism to lock the emptying mechanism, and when the second toy is combined to the clamping piece or the sucking piece, the linkage rod is triggered to move to unlock the emptying mechanism.

Optionally, a part of the linkage rod extends to two sides of the clamping piece or the sucking piece, and a part of the ejection mechanism extends to two horizontal sides of the linkage mechanism.

Additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 is a diagram illustrating the change in motion of a first toy and a second toy when they meet in one embodiment.

Fig. 2 is a diagram illustrating a motion change of the first toy and the second toy in one embodiment, which are turned over after being combined.

Fig. 3 is a diagram illustrating a variation in the behavior of a first toy transformed after ejecting a second toy according to one embodiment.

Fig. 4 is a perspective view of a first toy (with parts hidden) according to one embodiment.

Fig. 5 is another perspective view of the first toy of fig. 4 (with portions hidden).

Fig. 6 is a perspective view of a first toy (with parts hidden) according to one embodiment.

Fig. 7 is another perspective view of the first toy of fig. 6 (with portions hidden).

Fig. 8 is a diagram showing a change in the movement of the first toy and the second toy when they meet in another embodiment.

Fig. 9 is an expanded view of the second toy of the embodiment of fig. 8 after it has been fired away.

Reference numerals:

a linkage soaring push-shooting toy 1000,

A first toy 100, a combining opening 101,

A traveling mechanism 10, a traveling wheel 11,

The linkage mechanism 20, the sucking piece 21, the linkage rod 22, the linkage lock catch 221, the linkage elastic piece 23,

A deforming mechanism 30, a deforming piece 31, a deforming lock catch 32, a locking elastic piece 33,

A push-shooting mechanism 40, a push-shooting piece 41, a push-shooting locking piece 42, a push-shooting first locking piece 421, a push-shooting second locking piece 422, a locking hook end 4221, an unlocking end 4222, a back projection 4223, a push-shooting elastic piece 43, a push-shooting first locking spring 441, a push-shooting second locking spring 442,

An emptying mechanism 50, a turnover plate 51, a turnover elastic piece 52,

A chassis 60,

Second toy 200, unfolding assembly 210, unfolding member 211, inserter 212, magnetic strip 2121, and rotating plate 261.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

The structure of the linked flight launching toy 1000 according to the embodiment of the present invention will be described below with reference to the accompanying drawings.

A linked lofting and propelling toy 1000 according to an embodiment of the present invention, as shown in fig. 1 to 3, includes a first toy 100 and a second toy 200, the first toy 100 and the second toy 200 being two small toys independent of each other. Each toy can be played independently, the shape of each toy is not limited, and the toy can be a toy car, a toy top, a toy animal, a human-shaped toy or a toy daily article, and the like. The two toys can be combined by the self structure, and a series of linkage actions are generated after the two toys are combined, and the action change process is shown in figures 1-3.

First toy 100 includes a walking mechanism 10, a linkage mechanism 20, an evacuation mechanism 50, and a projectile mechanism 40, with linkage mechanism 20 coupling second toy 200 to first toy 100 as first toy 100 walks to second toy 200. After engagement, the release of the emptying mechanism 50 is triggered, either directly by the second toy 200 or by the release of the emptying mechanism 50 triggered by the linkage 20 when the engagement takes place. After the emptying mechanism 50 is unlocked, the first toy 100 is emptied, and since the first toy 100 and the second toy 200 are combined into a whole at this time, the first toy 100 is emptied to drive the second toy 200 to empty.

The first toy 100 is emptied to trigger the ejector mechanism 40 to unlock, here, the emptying mechanism 50 directly triggers the ejector mechanism 40 to unlock when the emptying mechanism 50 is emptied, the first toy 100 is emptied integrally to cause the ejector mechanism 40 to unlock, or the first toy 100 is dropped to the ground to cause the ejector mechanism 40 to unlock at the moment of emptying. For example, the emptying mechanism 50 includes a flipping panel, and the triggering end of the ejecting mechanism 40 is located at the flipping position of the flipping panel, when the flipping panel flips to the flipping position to eject the first toy 100, the triggering end of the ejecting mechanism 40 is triggered, and the ejecting mechanism 40 unlocks to drive the second toy 200 to disengage the linkage mechanism 20 and eject the second toy 100. For another example, the first toy 100 may have a gravity block therein, the top of the gravity block is connected to the shooting mechanism 40, when the first toy 100 is walking normally, the gravity block presses the bottom of the first toy 100 to unlock the shooting mechanism 40, when the first toy 100 is emptied and turned over, the gravity block presses the top of the first toy 100 at a certain moment, and the gravity block triggers the shooting mechanism 40 to unlock. After the projectile mechanism 40 is unlocked, the projectile mechanism 40 drives the second toy 200 off the linkage 20 and away from the first toy 100.

According to the linked soaring and ejecting toy 1000 provided by the embodiment of the invention, the first toy 100 can be automatically combined with the second toy 200 in the walking process, the second toy 200 can be driven to soar together, and the second toy 200 can be ejected after the second toy 200 soars.

In some embodiments, the traveling mechanism 10 includes a traveling wheel 11, the traveling wheel 11 may be a passive traveling wheel (i.e., the traveling wheel is driven by external force such as human power to travel passively), and the traveling wheel 11 may also be an active traveling wheel, for example, the traveling mechanism 10 further includes a traveling motor connected to the traveling wheel 11, a traveling energy storage mechanism (e.g., a spring), and the like. Specifically, the first toy 100 is a toy vehicle, and a plurality of road wheels 11 are provided at the bottom of the first toy 100.

In other embodiments of the present invention, the traveling mechanism 10 may also travel in other structures, which are not limited herein. For example, the first toy 100 is a sled, and the traveling mechanism 10 includes a skateboard or the like. For another example, the first toy 100 is a quadruped toy, and the walking mechanism 10 includes four swingable legs located on both sides of the animal, and the four legs alternately contact with the ground when swinging, thereby moving the toy seal. For another example, the first toy 100 is a rollable toy, and the walking mechanism 10 includes a driving mechanism for rolling the first toy 100, and the driving mechanism drives the first toy 100 to roll forward. Also for example, the first toy 100 is a top, and the traveling mechanism 10 includes a rotatable top tip located at the bottom center of the top, and the top is moved by the top tip contacting and rotating with the ground.

In some embodiments, linkage 20 includes a clamping member (not shown) for engaging second toy 200, such as two spring-coupled clamping bars defining a clamping opening therebetween, such that when first toy 100 is moved toward second toy 200, second toy 200 is squeezed into the clamping opening of first toy 100 and thereby clamped by the two clamping bars. For another example, when first toy 100 is a human toy, the holder is an arm of the human toy.

In other embodiments, as shown in fig. 4 and 5, linkage 20 includes a holder 21 for engaging a second toy 200. Alternatively, the holding member 21 is a magnet, or the surface of the holding member 21 is provided with an adhesive layer or the like.

In still other embodiments, the linkage 20 includes both the clamping member and the suction member 21 to improve the bonding stability.

Specifically, as shown in FIG. 4, linkage 20 further includes a linkage rod 22, linkage rod 22 being movably disposed within first toy 100. The linkage rod 22 is matched with the emptying mechanism 50 to lock the emptying mechanism 50, and when the second toy 200 is combined to the clamping piece or the sucking piece 21, the linkage rod 22 is triggered to move to unlock the emptying mechanism 50.

As shown in fig. 4, the linkage mechanism 20 further includes a linkage elastic member 23 connected to the linkage rod 22, and the linkage elastic member 23 is used for pushing the linkage rod 22 to move toward a position where the second toy 200 is combined with the first toy 100. As shown in fig. 1, a combining opening 101 is formed in the front side of the first toy 100, the sucking member 21 is located inside the first toy 100 and is arranged adjacent to the combining opening 101, and the linkage elastic member 23 pushes the linkage rod 22 to extend forward into the combining opening 101. When the first toy 100 encounters the second toy 200, a part of the second toy 200 is sucked in the coupling port 101 by the suction member 21. The second toy 200 pushes the coupling elastic member 23 backward when coupled. The linkage rod 22 is arranged, and when the joint is far away from the triggering position of the emptying mechanism 50, the transition of the linkage rod 22 can facilitate the structural layout. Of course, the design of the linkage bar 22 may be omitted when the junction is closer to the triggering of the evacuation mechanism 50.

In some embodiments, as shown in fig. 2, the evacuation mechanism 50 includes a flap 51 rotatably disposed at the bottom of the first toy 100, the flap 51 having a flap lock position and a flap unlock position, the flap 51 rotating from the flap lock position to the flap unlock position when the evacuation mechanism 50 is unlocked. When the turning plate 51 is unlocked, the turning plate 51 rotates, and the first toy 100 is bounced to empty by the instant beating of the turning plate 51 on the ground, and in some embodiments, the first toy 100 is wholly turned forwards or backwards after being emptied.

Specifically, as shown in fig. 5, the evacuation mechanism 50 includes a flip elastic member 52 connected to the flap 51, and optionally, the flip elastic member 52 is a torsion spring connected at the rotational axis of the flap 51.

More specifically, as shown in fig. 4 and 5, the linkage rod 22 is provided with a linkage latch 221, and when the linkage latch 221 is latched on the flap 51, the flap 51 is in the flap latch retention position.

In other embodiments, the evacuation mechanism 50 may also include a springboard (not shown) that snaps into the bottom of the first toy 100, the springboard being connected by a straight spring. When the evacuation mechanism 50 is unlocked, the springboard springs downward, and the springboard touches the ground to cause the first toy 100 to spring upward. For example, the first toy 100 is designed as a human-shaped toy, and both feet are provided with springboards so that the human-shaped toy can jump up vertically, while the second toy 200 is designed as a soccer ball, which can attract a soccer ball to the feet when the human-shaped toy runs into contact with the soccer ball through the traveling mechanism 10, and then the human-shaped toy jumps up, and then triggers the ejector mechanism 40 to unlock, thereby kicking the soccer ball out in the air.

In some embodiments, as shown in fig. 4-7, the ejection mechanism 40 includes: the shooting device 41 is used for shooting the second toy 200 away from the first toy 100, and the shooting locking device 42 is used for locking the shooting device 41. Specifically, as shown in fig. 4 and 5, the shooting mechanism 40 includes a shooting elastic member 43, the shooting elastic member 43 is used for pushing the shooting member 41, and the shooting member 41 is kept to have a tendency of shooting away the second toy 200.

Specifically, as shown in fig. 4, there are a plurality of the push-fire locks 42, and the plurality of push-fire locks 42 form multiple blockages of the push-fire 41, and one of the push-fire locks 42 is unlocked when the evacuation mechanism 50 is actuated. The multiple-locking arrangement is beneficial to reasonably setting the shooting time of the second toy 200. When the emptying mechanism 50 is not operated, one of the ejector locking pieces 42 can be ensured to lock the ejector 41, and the reliability of ejection control is improved.

More specifically, as shown in fig. 4 and 5, the ejector lock 42 includes an ejector first lock 421, the ejector first lock 421 is locked to the ejector 41 when the flap 51 is located at the flap lock position, and the flap 51 pushes the ejector first lock 421 to be unlocked when the flap 51 is located at the flap unlocking position.

As shown in fig. 4, the push mechanism 40 includes a push first locking spring 441, and the push first locking spring 441 is connected to the push first locking member 421 to keep the push first locking member 421 in a state of locking the push member 41. In the example of fig. 4, the shoot-through first spring 441 presses the shoot-through first lock 421 downwards, so that the shoot-through first lock 421 hooks the shoot-through member 41 for locking. When the turning plate 51 is turned to the turning plate unlocking position, the turning plate 51 pushes the ejection first lock 421 upwards, so that the ejection first lock 421 releases the ejection member 41.

Further, in multiple lockout, a projectile lock 42 is provided at the bottom of first toy 100 and is configured to be struck to unlock first toy 100 when it is airborne. That is, the push-fire lock 42 is unlocked after the first toy 100 and the second toy 200 are landed, so that the first toy 100 is prevented from being shot away from the second toy 200 while still being in a ground-off state. It can be understood that when the first toy 100 is turned over in the air, the shooting direction of the first toy 100 cannot be determined, and the second toy 200 may be shot in any direction, which may lead to attack on the playing child, so that the safety of playing can be improved by adding the push-shot lock 42 unlocked by falling to the ground. Of course, if first toy 100 is merely jumping in the original direction, the shooting direction is determined, in which case it may not be necessary to provide a plurality of push-fire locks 42.

In some embodiments, as shown in fig. 4 and 6, the projectile lock 42 includes a projectile second lock 422, the flap 51 restrains the projectile second lock 422 when the flap lock is in the flap lock position, the flap 51 unlocks the projectile second lock 422 when the flap 51 leaves the flap lock position, so that the projectile second lock 422 is locked on the projectile 41, and the ground impacts the projectile second lock 422 to unlock the projectile when the first toy 100 is empty.

This is because if the push-shooting second locking element 422 is in a state capable of locking the push-shooting element 41 without the constraint of the turning plate 51, that is, the first toy 100 is not empty, the push-shooting second locking element 422 is in a state capable of being unlocked by the ground, so that the ground is easy to unlock the push-shooting second locking element 422 when the first toy 100 is walking, and the arrangement of the push-shooting second locking element 422 is meaningless. In order to push the second locking element 422 to be in a state that the first toy 100 cannot be unlocked by the ground when walking, the turning plate 51 is adopted for restraining, so that the state that the push-shooting element 41 is locked and locked can be kept only after the first toy 100 is emptied by pushing the second locking element 422.

Specifically, as shown in fig. 5-7, the projectile second locking element 422 is rotatably coupled to the first toy 100, the projectile second locking element 422 has a locking hook end 4221 and an unlocking end 4222 about a rotation axis thereof, the locking hook end 4221 is configured to be hooked on the projectile 41, and a portion of the unlocking end 4222 is located below a lowermost end of the traveling mechanism 10 when the locking hook end 4221 is hooked on the projectile 41.

More specifically, as shown in fig. 6, the shoot mechanism 40 includes a shoot second bolt 442, the shoot second bolt 442 is connected to the shoot second lock 422, so that the shoot second lock 422 has a tendency to rotate the locking hook end 4221 upward to hook the shoot unit 41, and the shoot second bolt 442 has a tendency to rotate the unlocking end 4222 downward.

As shown in fig. 5, when the flap 51 is located at the flap lock position, the flap 51 presses against the ejection second lock 422, so that the ejection second lock 422 cannot rotate freely, and the unlocking end 4222 is kept above the lowermost end of the traveling wheel 11. As shown in fig. 6 and 7, when the flap 51 is located at the flap unlocking position, without the constraint of the flap 51, the second locking spring 442 pushes the locking hook end 4221 to rotate upward and hook the ejector 41, and the second locking spring 442 pushes the unlocking end 4222 to rotate downward, so that a part of the unlocking end 4222 is located above the bottommost end of the travelling wheel 11. This process occurs when the first toy 100 is emptied, and when the first toy 100 falls to the ground, the unlocking end 4222 contacts the ground, the ground pushes the projectile second locking member 422 to rotate reversely, so that the locking hook end 4221 releases the projectile 41, and then the projectile 41 moves forward under the action of the projectile elastic member 43.

In some embodiments, as shown in fig. 4, a back projection 4223 is formed on the unlocking end 4222, and when the flap 51 presses against the ejector second locking element 422, the back projection 4223 is caught on the ejector 41. That is to say, when the first toy 100 is not empty, the fire pushing second locking piece 422 limits the fire pushing piece 41 to move in the opposite direction of fire pushing, that is, the back protrusion 4223 limits the fire pushing piece 41 to move backwards in fig. 4, at this time, the fire pushing first locking piece 421 limits the fire pushing piece 41 to move forwards, and the position of the fire pushing piece 41 is relatively fixed under the constraint of the two fire pushing locking pieces 42, so as to avoid the fire pushing piece 41 from contacting other components due to any movement in the first toy 100.

Specifically, as shown in fig. 4, a portion of the linkage rod 22 extends to both sides of the clamping or sucking member 21, and a portion of the ejection mechanism 40 extends to both horizontal sides of the linkage mechanism 20. Both sides of the front end of the linkage rod 22 can be pushed and moved backwards, both sides of the front end of the pushing and shooting mechanism 40 can push objects forwards, the double-point stress action surface is wide, the movement is more stable, and the space utilization rate of the joint of the first toy 100 and the second toy 200 can be fully utilized by arranging the linkage rod on both sides of the clamping piece or the sucking and holding piece 21.

In some embodiments, as shown in fig. 3, first toy 100 further includes: a deforming mechanism 30, the deforming mechanism 30 comprising: a deforming piece 31 and a deforming lock catch 32. The deforming member 31 is retractably provided on the first toy 100, the deforming latch 32 is slidably provided on the first toy 100, and the deforming latch 32 is configured to be always slid toward a position where it is engaged with the deforming member 31 to lock the deforming member 31. Wherein the shooting mechanism 40 triggers the transformable lock 32 to unlock when the second toy 200 is driven to disengage. By the arrangement, the change playing method of the linked soaring and pushing toy 1000 is enriched, and the interestingness is further improved.

In addition to first toy 100 being expandable by deformation mechanism 30, second toy 200 may also be contoured. For example, the second toy 200 includes a deployment element 210, and the ejection mechanism 40 may trigger the deformation mechanism 30 of the first toy 100 when the second toy 200 is driven to disengage, and the deployment element 210 of the second toy 200 may be unlocked, so that both toys may be changed into another configuration.

Specifically, as shown in fig. 4, the transformation locker 32 is provided on the first toy 100 to be movable back and forth, and the transformation mechanism 30 further includes a locking elastic member 33, and the locking elastic member 33 is used to push the transformation locker 32 to move back to lock the transformation member 31. As shown in fig. 3, the first toy 100 has a chassis 60, the bottom of the transformation shackle 32 is located in the chassis 60, the transformation element 31 is located above the chassis 60, and the top of the transformation shackle 32 extends out of the chassis 60 and is locked on the transformation element 31.

Further, as shown in fig. 3, there are a plurality of deformation members 31, and the plurality of deformation members 31 form an interlocking deformation structure, that is, a first deformation member 31 is locked by a deformation lock 32, a second deformation member 31 is locked by the first deformation member 31, and so on. When the deformation lock catch 32 is unlocked, the first deformation piece 31 is unfolded under the driving of the deformation spring; after the first deformation member 31 is actuated, the second deformation member 31 is unlocked, the second deformation member 31 is unfolded under the driving of the deformation spring, and the like.

The first embodiment is as follows:

an example embodiment of the action play of the linked flight ejection toy 1000 is described below with reference to fig. 1-3.

The first toy 100 is a toy car, the front side of the toy car chassis 60 is provided with a combination opening 101, a magnet is arranged in the combination opening 101, the second toy 200 is a disc, and an iron rod is arranged in the disc.

As shown in fig. 1, when the toy vehicle travels forward, the disk is ejected toward the toy vehicle, the disk is caught at the coupling port 101, and the disk is caught at the coupling port 101 by the attraction of the iron rod and the magnet.

The clamped disc pushes the linkage rod 22 backwards to enable the linkage lock catch 221 to unlock the turning plate 51, the turning plate 51 is driven by the elastic force of the turning elastic piece 52 to rotate backwards, and the turning plate 51 touches the ground when rotating to enable the toy car clamping the disc to be completely emptied and turned over. The process of the change is shown in fig. 2.

After the flap 51 rotates, the push-shooting second locking element 422 is released, and the push-shooting second locking element 422 rotates under the torque force of the push-shooting second locking spring 442, so that the locking hook end 4221 is hooked on the push-shooting element 41. After the flap 51 rotates 180 degrees, the flap 51 pushes the ejection first lock 421 to move upward, so that the ejection first lock 421 releases the ejection element 41. When the toy car is on the ground, the unlocking end 4222 on the ejection second locking piece 422 contacts the ground, the ground reaction force makes the ejection second locking piece 422 reverse against the elastic force of the ejection second locking spring 442, the ejection second locking piece 422 releases the ejection piece 41, that is, all the ejection locking pieces 42 on the ejection piece 41 are unlocked, and the ejection piece 41 moves forward under the action of the ejection elastic piece 43. The front end of the ejector 41 is pressed against the disk to eject the disk forward against the magnetic attraction. In the process that the ejection piece 41 moves forwards, the deformation lock catch 32 is driven to move forwards, the deformation piece 31 is unlocked, the deformation piece 31 is unfolded under the action of the deformation spring, and the toy car is changed into a toy eagle.

Example two:

an action play method of the linked flight ejection toy 1000 of another embodiment is described below with reference to fig. 8 to 9.

The first toy 100 is a toy car, the front side of the chassis 60 of the toy car is provided with a combining opening 101, a magnet is arranged in the combining opening 101, the second toy 200 is another toy car, the rear end of the toy car is provided with a plug board 212, and the plug board 212 is provided with a magnetic attraction strip 2121 (such as an iron wire).

As shown in fig. 8, when the first toy 100 walks forward and reaches the second toy vehicle 200, the insert plate 212 is caught at the coupling opening 101, and the insert plate 212 is caught at the coupling opening 101 by the attraction of the magnetic attraction strip 2121 and the magnet.

The inserted inserting plate 212 pushes the linkage rod 22 backwards, and the generated linkage reaction is basically the same as that of the first embodiment, namely, the linkage rod 22 moves backwards to enable the linkage lock catch 221 to unlock the turning plate 51, the turning plate 51 rotates backwards under the driving of the elastic force of the overturning elastic piece 52, and the turning plate 51 touches the ground when rotating, so that the first toy 100 is overturned in the air with the second toy 200. After the flap 51 rotates, the push-shooting second locking element 422 is released, and the push-shooting second locking element 422 rotates under the torque force of the push-shooting second locking spring 442, so that the locking hook end 4221 is hooked on the push-shooting element 41. After the flap 51 rotates 180 degrees, the flap 51 pushes the ejection first lock 421 to move upward, so that the ejection first lock 421 releases the ejection element 41. When the two toy vehicles fall to the ground, the unlocking end 4222 on the ejection second locking piece 422 contacts the ground, the ground reaction force makes the ejection second locking piece 422 reverse against the elastic force of the ejection second locking spring 442, the ejection second locking piece 422 releases the ejection piece 41, that is, all the ejection locking pieces 42 on the ejection piece 41 are unlocked, and the ejection piece 41 moves forward under the action of the ejection elastic piece 43.

The front end of the ejector 41 abuts on the insert 212, so that the second toy 200 is ejected forward against the magnetic attraction. In the process that the ejection piece 41 moves forwards, the deformation lock catch 32 is driven to move forwards, so that the deformation piece 31 is unlocked, the deformation piece 31 is unfolded under the action of the deformation spring, and the first toy 100 is changed into the toy eagle.

The ejected second toy 200 may also be triggered to interlock under certain conditions. For example, as shown in fig. 9, the second toy 200 includes a rotating plate 261 at the bottom, and when the rotating plate 261 is triggered to rotate by touching the lock, the rotating plate 261 instantaneously beats the ground to make the second toy 200 pop up and empty, and even make the second toy 200 entirely flip forward or backward after empty.

As further shown in fig. 9, second toy 200 includes a locked deployment assembly 210, deployment assembly 210 including at least one deployment member 211, deployment assembly 210 being triggered to unlock deployment member 211, causing second toy 200 to change from the toy vehicle to the configuration of the human-type toy.

The triggering condition of deployment assembly 210, and rotation plate 261, of second toy 200 may be in a manner known in the art, such as triggering rotation plate 261 to unlock after second toy 200 has traveled a certain distance, and triggering deployment assembly 210 to unlock after rotation plate 261 has been actuated.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" 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; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In the description herein, references to the description of the terms "embodiment," "example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. While embodiments of the invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.

Claims (10)

1. A linked flight propelling toy, comprising: a first toy and a second toy,

the first toy comprises a walking mechanism, a linkage mechanism, an emptying mechanism and a pushing mechanism, the linkage mechanism combines the second toy with the first toy when the first toy walks to the second toy,

after combination, the emptying mechanism is triggered to unlock so that the first toy drives the second toy to empty, and after the first toy empties, the ejection mechanism is triggered to unlock,

after the push-shooting mechanism is unlocked, the push-shooting mechanism drives the second toy to be separated from the linkage mechanism and shoot away from the first toy.

2. A linked lofting projectile toy according to claim 1, wherein said first toy further comprises: a deformation mechanism, the deformation mechanism comprising:

a deforming member, the deforming member being retractably provided on the first toy;

the deformation lock catch is arranged on the first toy in a sliding mode and is configured to slide towards a position matched with the deformation piece normally so as to lock the deformation piece; wherein the content of the first and second substances,

the ejection mechanism triggers the deformable lock catch to unlock when driving the second toy to disengage.

3. A linked lofting projectile toy according to claim 1, wherein said projectile mechanism includes:

a projectile for ejecting the second toy away from the first toy;

the ejection locking piece is multiple, multiple ejection locking pieces form multiple sealing of the ejection pieces, and one of the ejection locking pieces is unlocked when the emptying mechanism acts.

4. A linked lofting projectile toy according to claim 3, wherein one of said projectile locks is provided at a bottom of said first toy and is configured to be unlocked by impact upon landing of said first toy.

5. A linked lofting and propelling toy according to claim 3, wherein the lofting mechanism includes a flap rotatably provided at the bottom of the first toy, the flap having a flap lock position and a flap unlock position, the flap rotating from the flap lock position to the flap unlock position upon unlocking of the lofting mechanism;

the push-shooting locking piece comprises a push-shooting first locking piece, when the turning plate is located at the position where the turning plate is locked, the push-shooting first locking piece is locked on the push-shooting piece, and when the turning plate is located at the position where the turning plate is unlocked, the turning plate pushes the push-shooting first locking piece to be unlocked.

6. A linked lofting projectile toy according to claim 5, wherein said projectile lock includes a projectile second lock, said flap constrains said projectile second lock when in a flap lock position, said flap unlocks said projectile second lock when out of said flap lock position so that said projectile second lock is locked to said projectile member, said ground impacting said projectile second lock to unlock when said first toy is lofted and landed.

7. A linked lofting projectile toy according to claim 6, wherein said projectile second locking element is pivotally connected to said first toy, said projectile second locking element having a locking hook end and an unlocking end about a pivot axis thereof, said locking hook end being adapted to hook onto said projectile element, and a portion of said unlocking end being located below a lowermost end of said travel mechanism when said locking hook end is hooked onto said projectile element;

when the turning plate is positioned at the turning plate locking position, the turning plate is pressed against the push-shooting second locking piece, and the unlocking end is positioned above the bottommost end of the travelling mechanism.

8. A linked lofting projectile toy according to claim 7, wherein said release end is formed with a back projection, said back projection being engaged by said projectile when said flap is pressed against said projectile second locking element.

9. A linked lofting projectile toy according to claim 1, wherein said linkage mechanism comprises:

a grip and/or a suction for engaging the second toy;

the linkage rod is movably arranged in the first toy, the linkage rod is matched with the emptying mechanism to lock the emptying mechanism, and when the second toy is combined to the clamping piece or the sucking piece, the linkage rod is triggered to move to unlock the emptying mechanism.

10. A linked lofting projectile toy according to claim 9, wherein a portion of said linkage rod extends to both sides of said gripping or suction member and a portion of said projectile mechanism extends to both horizontal sides of said linkage mechanism.

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