CN210874087U - Motion triggered toy vehicle - Google Patents

Abstract

The utility model discloses a motion triggered toy car, include: a vehicle body; an actuation member; a motion trigger assembly, the motion trigger assembly comprising: the first meshing part is connected with a driven wheel of the vehicle body; the second meshing part is driven by the first meshing part to rotate when meshed with the first meshing part; the unlocking piece is connected with the second meshing piece so as to be driven by the second meshing piece to rotate; the locking piece is movable between a locking position and an unlocking position, the locking piece is configured to be always kept at the locking position, the unlocking piece can push the locking piece to move towards the unlocking position when rotating, the locking piece locks the action piece when at the locking position, and the locking piece releases the action piece when at the unlocking position; the action driving piece is matched with the action piece and used for driving the action piece to move or fly away from the vehicle body when the action piece is released. The utility model discloses a toy car, novel, interesting, the security of playing is high.

Description

Motion triggered toy vehicle

Technical Field

The utility model relates to a toy field especially relates to a motion triggered toy car.

Background

The triggering mode of a general sport type toy, whether the toy is deformed, disassembled, combined or overturned, is usually triggered by collision, or by unlocking and triggering through a magnetic principle, or by electrically controlled unlocking and triggering. Some toys can utilize a return mechanism to enable the toy vehicle to jump in the air and then deform during the driving process. However, no matter which of the above methods is adopted for control, the structure is relatively complex, the cost is high, the use effect of the product is easy to reduce, and the product is easy to damage. Therefore, the motion trigger type of the toy in the market has a very large expansion space.

SUMMERY OF THE UTILITY MODEL

The utility model discloses aim at solving one of the technical problem that exists among the prior art at least. Therefore, the utility model provides a motion triggered toy car can utilize the simple walking action of toy car self, unlocks some functions of toy car, and simple structure realizes that the product is miniaturized, conveniently carries and plays.

According to the utility model discloses motion triggered toy car, include: a vehicle body; a road wheel comprising a driven wheel; the action piece is movably or flyably arranged on the vehicle body; a motion trigger assembly, the motion trigger assembly comprising: the first meshing component is connected with the driven wheel; the second meshing part is driven by the first meshing part to rotate when meshed with the first meshing part; the unlocking piece is connected with the second meshing piece so as to be driven by the second meshing piece to rotate; the locking piece is movable between a locking position and an unlocking position, the locking piece is configured to be always kept at the locking position, the unlocking piece can push the locking piece to move towards the unlocking position when being rotated, the locking piece locks the action piece when at the locking position, and the locking piece releases the action piece when at the unlocking position; the action driving piece is matched with the action piece and used for driving the action piece to move or fly away from the vehicle body when the action piece is released.

According to the utility model discloses motion triggered toy car, because the walking of follower wheel makes the motion trigger subassembly can unblock locking piece, action driving piece can drive action piece exhibition action after the locking piece unblock, make child can see the toy car that the motion triggered directly perceivedly and just produced the action after walking a period, rather than just producing the action at present of toy car walking, the novelty of toy car has been increased on the one hand, on the other hand also makes this toy car just move after pulling open appropriate distance with the departure, reduce the action and injure the possibility of staying at the child of departure. And the action pieces are added, so that the toy car has the appearance transformation capability or the attack capability, and the overall interest and the visual impact effect of the toy car are enhanced. Through setting up the rotation power transmission to the unlocking piece that the meshing structure will take turns to, through the unlocking piece unblock of unlocking piece control locking piece, make the toy car can unblock the locking piece when the walking, thereby trigger opening and close or the function switching of certain functional unit, this is equivalent to design out the new mode of opening and close/switching functional unit on the toy car, make the toy car more novel, it is interesting, can save the inside structural design who is used for unblock function of toy car, the design that makes the product can be more miniaturized, so conveniently carry and play, can also reach unexpected functional effect, and simple structure can effectively improve the performance and the life of toy car in the toy car. Wherein, adopt the rotation power of meshing structure transmission walking wheel, can ensure power transmission's reliability, be convenient for moreover according to toy car inner structure adjust out required overall arrangement mode, power transmission direction, this kind of motion trigger assembly suitability is strong on each type toy car.

In some embodiments, the first engagement member is a worm, the second engagement member is a worm gear, and the unlocking member is an eccentric.

In some embodiments, the motion trigger assembly further comprises: and the rotating reset piece is used for driving the second engagement piece to rotate to an initial angle, and the rotating reset piece is connected to the second engagement piece or the unlocking piece.

Specifically, the unlocking piece is coaxially connected to the second meshing piece, and the rotating reset piece is a torsion spring and is coaxially arranged on the unlocking piece.

In some embodiments, the first engaging member is horizontally disposed on the vehicle body, the first engaging member is movable between an upper stop position at which the first engaging member is engaged with the second engaging member and a lower stop position at which the first engaging member is disengaged from the second engaging member.

Specifically, the second engaging member or the unlocking member is provided with a limiting block, and the vehicle body is provided with a convex edge for limiting the rotation angle of the limiting block.

Specifically, the action piece is a turning plate which is rotatably arranged at the bottom of the vehicle body, and when the turning plate is released, the action driving piece drives the turning plate to rotate and contact with the ground so as to enable the toy vehicle to be emptied and turned.

Optionally, the action member is a plurality of unfolding members, the plurality of unfolding members are locked by the motion trigger assembly, or the motion trigger assembly only locks a part of the unfolding members, and the rest of the unfolding members are locked by the other unfolding members, and when the unfolding members are unlocked, the action driving member drives the unfolding members to deform the toy car.

In one particular example, the motion-activated toy vehicle has a coin holder for holding or attracting a toy coin.

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 schematic view of a motion activated assembly carried by a toy vehicle in a locked position according to an embodiment of the present invention.

Fig. 2 is an exploded view of the structure of fig. 1.

Fig. 3 is a top perspective view of the motion activated toy vehicle of embodiment 1.

Fig. 4 is a bottom perspective view of the motion activated toy vehicle of embodiment 1.

Fig. 5 is a schematic view of fig. 4 with parts omitted.

Fig. 6 is a schematic view showing one direction of a deformed state of the motion-triggered toy vehicle of embodiment 1.

Fig. 7 is another directional schematic view of a deformed state of the motion-triggered toy vehicle of embodiment 1.

Fig. 8 is a cross-sectional view of a deformed state of the motion-triggered toy vehicle of embodiment 1.

Fig. 9 is a perspective view of the motion activated toy vehicle of embodiment 2.

Fig. 10 is an exploded view of the motion activated toy vehicle of embodiment 2.

Fig. 11 is a schematic view of the motion-triggered toy vehicle of embodiment 2 with parts omitted in the bottom view.

Fig. 12 is a perspective view of the motion activated toy vehicle of embodiment 3.

Figure 13 is a modified schematic view of the motion activated toy vehicle of example 3.

FIG. 14 is an exploded view of a part of the structure of embodiment 3.

Reference numerals:

a toy car 1000,

A motion trigger component 1,

A first engaging member 11, a second engaging member 12, a mounting groove 121, an unlocking member 13, a protrusion 131, a locking member 14, a locking hook 141, a rotation returning member 15, a stopper 17, a locking elastic member 18, a fixing shaft 19, a locking pin, a locking spring, a locking pin,

A vehicle body 2, a convex edge 21,

A traveling wheel 3, a wheel shaft 30, a driving wheel 31, a driven wheel 32,

An action piece 4, a turning plate 41, an expansion piece 42, a hook 421, a connecting rod 44,

An operation driving member 5,

A coin holding part 6, a magnetic attraction piece 61, a coin clamping piece 62,

A spring tooth box 71,

Toy coin 200.

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 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 drawings are exemplary only for the purpose of explaining the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "center", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are merely for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, are not to be construed as limiting the present invention. Furthermore, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; 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 meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

A motion trigger assembly 1 according to an embodiment of the present invention is described below with reference to the accompanying drawings.

According to the utility model discloses motion trigger assembly 1, as shown in fig. 1 and 2, include: a first engaging member 11, a second engaging member 12, an unlocking member 13, and a locking member 14. The first engaging member 11 is adapted to be coupled to the road wheels 3 of the toy vehicle 1000, the second engaging member 12 is rotated by the first engaging member 11 when engaged with the first engaging member 11, the unlocking member 13 is coupled to the second engaging member 12 to be rotated by the second engaging member 12 with the second engaging member 12, the locking member 14 is movable between a locked position and an unlocked position, the locking member 14 is configured to be always maintained in the locked position, and the unlocking member 13 pushes the locking member 14 to move toward the unlocked position when rotated.

The toy vehicle 1000 has a feature that can be turned on and off when the locking element 14 is unlocked, and the feature can be an action 4, a sound emitting element, a light emitting element, or the like on the toy vehicle 1000. For example, the functional component is a sound generator, and when the toy vehicle 1000 is powered on, the locking member 14 is in the locked position and the sound generator generates a sound effect; when the locking member 14 is moved to the unlocked position, the locking member 14 triggers the sound emitting member to turn off or to emit another sound effect. That is, when the locking member 14 moves from the locked position to the unlocked position, the function unit can be turned on, turned off, or switched.

The driving mode of how the travelling wheels 3 travel on the toy car 1000 is not limited, the travelling wheels 3 can be driving wheels 31 which are driven to rotate by motors, power storage devices (such as springs and inertia wheels) and the like, and the travelling wheels 3 can also be driven wheels 32, namely when the toy car 1000 moves on the ground, the travelling wheels 3 are rotated by friction between the travelling wheels 3 and the ground.

Motion trigger assembly 1 sets up the structure, and when toy car 1000 walked subaerial, walking wheel 3 can drive first meshing piece 11 and rotate, and first meshing piece 11 can drive second meshing piece 12 and rotate, and second meshing piece 12 drives unlocking piece 13 again and rotates, and unlocking piece 13 pivoted in-process can unblock locking piece 14. Wherein, adopt the meshing structure to transmit the rotation of walking wheel 3 to unlocking piece 13, for other modes, the structure is simpler on the one hand, easy overall arrangement, and on the other hand rotates the transmission and ensures easily. For example, the first engaging member 11 and the second engaging member 12 are replaced by two smooth wheels in contact with each other, and the two smooth wheels are driven by the contact, but when the toy car 1000 is knocked and the like, the distance between the two smooth wheels is increased, and the rotation transmission is easily failed.

In addition, in the motion trigger assembly 1, the rotation power of the walking wheel 3 is transmitted to the locking piece 14 through the first meshing piece 11, the second meshing piece 12 and the unlocking piece 13 in sequence, and is not directly transmitted to the locking piece 14 through the walking wheel 3, so that the reliability of rotation transmission can be ensured, the components can be utilized, and various layout forms can be set for meeting the requirements of various toy vehicles 1000. For example, in some examples, both the engaging members are spur gears, and the rotational power of the road wheels 3 can be transmitted to the locking member 14 linearly; in an example where both engagement members are bevel gears, the rotational power of the road wheels 3 can be diverted and transmitted to the locking member 14.

Wherein the locking member 14 is configured to always remain in the locked position such that the locking member 14 can automatically return to the locked position when the locking member 14 is not unlocked by the unlocking member 13 to ensure the normal operation of the next play. The locking member 14 can be automatically reset by the locking elastic member 18, and the locking member 14 can also be automatically reset by its own weight, elastic force, and the like, which are not limited in this respect.

According to the utility model discloses subassembly 1 is triggered in motion, through setting up the rotation power transmission to the unlocking piece 13 that the structure will take turns 3, through 14 unblocks of unlocking piece 13 control locking piece, make toy car 1000 unblock locking piece 14 when the walking, thereby trigger opening and close or the function switching of certain functional unit, this is equivalent to design the new mode of opening and close/switching functional unit on toy car 1000, toy car 1000 can self trigger through the motion promptly, make toy car 1000 more novel, interesting. Wherein, adopt the rotation power of meshing structure transmission walking wheel 3, can ensure power transmission's reliability, be convenient for moreover according to the overall arrangement mode, the power transmission direction that toy car 1000 inner structure adjusted out needs, this kind of motion triggers subassembly 1 suitability is strong on each toy car 1000. Therefore, the structural design of the unlocking function in the toy car 1000 can be saved, the product design can be more miniaturized, and the toy car is convenient to carry and play, such as being directly arranged in a pocket; or the saved space in the toy car 1000 is used for designing other functional parts, thereby further enriching the functional effect of the toy car 1000 and achieving unexpected functional effects, such as actions of following fighting, jumping and turning, turning around, deforming, integrating, splitting, shooting and the like, or sounding, lighting, even sounding and lighting on the basis of actions and the like; and the simplified structure in the toy vehicle 1000 can effectively improve the performance and the service life of the toy vehicle 1000.

In some embodiments, as shown in fig. 1 and 2, the first meshing member 11 is a worm, the second meshing member 12 is a worm wheel, and the unlocking member 13 is an eccentric wheel. When the cam projection 131 rotates, it will abut against the locking member 14, causing the locking member 14 to swing or move or rotate, so that the locking member 14 unlocks the function/functions, for example, the action 4.

For example, in the example of fig. 1 and 2, the movement triggering assembly 1 comprises a fixed shaft 19, on which the worm wheel and the eccentric are housed, the bottom of the fixed shaft 19 resting on the locking element 14, on the one hand the locking element 14 supporting the lower end of the fixed shaft 19 and, on the other hand, the fixed shaft 19 defining the direction of movement of the locking element 14. In the exploded view of fig. 2, the worm wheel and the eccentric are turned 90 degrees in relation to the fixed shaft 19, wherein the worm wheel and the eccentric are arranged in one piece, the eccentric is arranged to push the locking member 14 backwards, the locking spring 18 is arranged to push the locking member 14 forwards, and the displacement of the locking member 14 is different when the outer contour of the eccentric rests against the locking member 14 at different positions.

The meshing structure adopts a worm gear-worm structure, and the worm is connected to the traveling wheels 3, so that the effects of speed reduction and torque increase during power transmission can be realized, and the occupied space of the motion trigger assembly 1 can be greatly reduced. Specifically, the traveling wheels 3 of the toy vehicle 1000 themselves need the wheel shafts 30 to support and connect the traveling wheels 3 to the body 2 portion of the toy vehicle 1000, and the first engaging member 11 is provided as a worm, so that the worm can be arranged by using the wheel shafts 30 of the traveling wheels 3, or the arrangement of other components is difficult because an excessive space is not needed on the toy vehicle 1000.

And the motion trigger assembly 1 adopts a structure of a worm, a worm wheel and an eccentric wheel, and can also realize delayed unlocking of the locking piece 14. In particular, the locking element 14 is located in the pivoting range of the eccentric, which, after a certain angle of rotation, unlocks the locking element 14, i.e. the eccentric itself has a time-delay function. And the matching between the worm and the worm wheel greatly reduces the rotating speed of the travelling wheel 3 and then transmits the rotating speed to the eccentric wheel, so that the unlocking time is further delayed.

Optionally, motion trigger assembly 1 may further include an intermediate gear(s) (not shown), the eccentric being disposed on one of the intermediate gears, the worm gear being engaged with the intermediate gear, or the worm gear being engaged with the intermediate gear via another intermediate gear, such that the transmission ratio may be changed to achieve a delay in triggering, i.e., toy vehicle 1000 may not unlock locking member 14 until it has traveled further. Even if the transmission speed ratio is not changed, the position of the eccentric can be adjusted by providing the intermediate gear when the locking member 14 is located farther from the axle 30 of the road wheel 3.

The embodiment of the utility model provides an in, because structural variation is various, consequently the eccentric wheel can with the coaxial setting of worm wheel, the eccentric wheel also can with worm wheel eccentric settings, the eccentric wheel can also set up on foretell intermediate gear.

In some embodiments, the motion trigger assembly 1 comprises: a first meshing member 11, a second meshing member 12, at least one intermediate gear, an unlocking member 13 and a locking member 14, wherein one of the intermediate gears is designed as a clutch gear, so that the rotational power of the traveling wheel 3 is transmitted to the unlocking member 13 in one traveling direction, and the rotational power of the traveling wheel 3 is not transmitted to the unlocking member 13 in the other traveling direction. For example, when the toy vehicle 1000 travels forward a distance, the locking member 14 may be unlocked, and when the toy vehicle 1000 travels backward, the worm drives the clutch gear to be in a disengaged state, so that power is not transmitted to the eccentric wheel, thereby preventing false triggering.

In some embodiments, as shown in fig. 5, the motion trigger assembly 1 further comprises: and a rotating reset piece 15, wherein the rotating reset piece 15 is used for driving the second engaging piece 12 to rotate to an initial angle, and the rotating reset piece 15 is connected to the second engaging piece 12 or the unlocking piece 13. After getting rid of the hindrance on the walking wheel 3 like this, rotate reset piece 15 and can drive motion trigger assembly 1 and resume to initial condition, need not to trigger assembly 1 unblock by artifical automatic re-setting after accomplishing at the motion, avoid influencing toy car 1000 function performance when playing next time.

For example, the road wheels 3 are driven wheels 32, and when the toy vehicle 1000 is triggered once, the toy vehicle 1000 can be taken up, so that the road wheels 3 are separated from the ground, and after the ground friction force does not exist, the movement triggering assembly 1 can be driven to reset by rotating the resetting piece 15. For another example, the road wheels 3 are driving wheels 31, and after the toy vehicle 1000 is triggered once, the driving wheels 31 are disconnected from the power source, or the power source has very small acting force on the driving wheels 31, and the rotating reset piece 15 can drive the motion trigger assembly 1 to reset.

Specifically, the unlocking member 13 is coaxially connected to the second engaging member 12, and the rotating returning member 15 is a torsion spring and coaxially provided on the unlocking member 13. Since the second engaging member 12 itself needs to be rotationally reset, the second engaging member 12 is rotationally driven to be reset by the torsion spring, the reset reliability is higher, and the torsion spring is very easy to set the mounting position.

Alternatively, the eccentric wheel is integrally formed on a worm wheel, the worm wheel is provided with a mounting groove 121 on an end surface, and the torsion spring is disposed in the mounting groove 121.

In the embodiment of the present invention, the motion trigger assembly 1 may be configured to be selectively driven.

In some embodiments, as shown in fig. 2, the second engaging member 12 is an incomplete gear, or in a scheme with an intermediate gear, an intermediate gear is an incomplete gear, that is, teeth on the incomplete gear are not arranged around a circle, and teeth are arranged on only a part of angles of the incomplete gear, so that when the first engaging member 11 rotates, the rotation angle of the unlocking member 13 is limited by the angle range of the teeth, and this arrangement can prevent the unlocking member 13 from over-rotating. For example, the unlocking piece 13 can unlock the locking piece 14 at the maximum angle in the normal transmission direction, and when the first meshing piece 11 rotates continuously in the normal transmission direction, the unlocking piece 13 only stops at the maximum angle, so that the unlocking piece 13 can be prevented from rotating at the maximum angle when not completely unlocked in some schemes, and the locking piece 14 can be completely unlocked when the walking wheel 3 meets the conditions due to the design of an incomplete gear.

In another embodiment, as shown in fig. 14, a stop block 17 is provided on the second engaging member 12 or the unlocking member 13, and then a convex edge 21 for limiting the rotation angle of the stop block 17 is provided on the body 2 of the toy vehicle 1000, so as to limit the misoperation when the second engaging member 12 or the unlocking member 13 rotates reversely, thereby improving the safety of the toy vehicle 1000.

Specifically, when the second engaging piece 12 or the unlocking piece 13 is located at the initial angle, the unlocking piece 13 cannot unlock the locking piece 14. If the walking wheels 3 are rotated along the reverse direction of the normal driving direction due to misoperation at the moment, the unlocking piece 13 can unlock the locking piece 14 after rotating for a section, so that the functional components can act, and potential safety hazards exist on the safety of children in certain types of toy vehicles 1000. For example, if a child holds toy vehicle 1000 and reverses by hand, and the feature is a motion part, toy vehicle 1000 may move while the motion part is in the child's hand, and may injure the child.

In order to prevent that child from holding toy car 1000 when pulling backward, lead to the mistake to touch because of the front wheel lands under the state of coming, make toy car 1000 warp and hit child's hand, so be equipped with stopper 17 beside the eccentric cam of gear, this stopper 17 stretches into on the vehicle bottom frame downwards, cooperate with a chimb 21 of vehicle bottom frame rear end, thereby inject stopper 17 anticlockwise rotation, when the front wheel moves backward promptly, can drive gear anticlockwise rotation, but because chimb 21 is to stopper 17's injecion, so the gear can't take place to rotate, thereby avoid eccentric cam's bulge 131 to rotate the rear and trigger locking piece 14 unblocks.

In some embodiments, the first engaging member 11 is horizontally disposed, and the first engaging member 11 is movable between an upper stop position where the first engaging member 11 is engaged with the second engaging member 12 and a lower stop position where the first engaging member 11 is disengaged from the second engaging member 12. The axle 30 of the road wheel 3 is designed to move up and down on the toy vehicle 1000, the first engaging member 11 is engaged with the second engaging member 12 when the axle 30 moves to the uppermost position, and the first engaging member 11 is disengaged from the second engaging member 12 when the axle 30 is located below the position.

With such a design, more interesting play may be provided on toy vehicle 1000. For example, when the toy car 1000 is placed on the ground to be driven, the first engaging member 11 is engaged with the second engaging member 12, and the road wheel 3 rotates to transmit the rotation to the unlocking member 13, so that the locking member 14 can be unlocked; when a child lifts the toy car 1000, the child holds the car body 2 of the toy car 1000 instead of holding the hand on the walking wheels 3 under the rough condition, at the moment, the walking wheels 3 fall under the action of gravity to drive the first engaging part 11 to fall to the stopping position, so that the first engaging part 11 is disengaged from the second engaging part 12, and even if the child pulls the walking wheels 3 with hands or the walking wheels 3 touch clothes to rotate, the locking part 14 cannot be unlocked. When a child puts the toy car 1000 back on the ground, the car body 2 falls under the action of gravity, the walking wheels 3 rise relative to the car body 2 to drive the first engaging member 11 to rise to the upper stop position, and therefore the first engaging member 11 is engaged with the second engaging member 12. The design not only increases the interest of the toy car 1000, but also increases the play safety of the toy car 1000 under the condition that the functional component is a moving part, and reduces the condition that children are injured due to misoperation after picking up the toy car 1000.

A motion triggered toy vehicle 1000 according to an embodiment of the present invention is described below with reference to the drawings.

A motion-triggered toy vehicle 1000 according to an embodiment of the present invention, as shown in fig. 3-8, includes: the vehicle body 2, the road wheels 3, the action piece 4, the motion trigger component 1 and the action driving piece 5. The travelling wheels 3 are arranged on the vehicle body 2, the travelling wheels 3 comprise driven wheels 32, and the action part 4 is movably or flyably arranged on the vehicle body 2.

The motion trigger assembly 1 is the motion trigger assembly 1 of the toy vehicle 1000 according to the above embodiment of the present invention, and the structure of the motion trigger assembly 1 is not described herein again. Wherein the first engaging member 11 is connected to the driven wheel 32, the locking member 14 locks the operating member 4 in the locked position, and the locking member 14 releases the operating member 4 in the unlocked position. The action driving piece 5 is matched with the action piece 4, and the action driving piece 5 is used for driving the action piece 4 to move or fly away from the vehicle body 2 when the action piece 4 is released.

According to the utility model discloses motion triggered toy car 1000, because the walking from driving wheel 32 makes motion trigger subassembly 1 can unblock locking piece 14, action driving piece 5 can drive action 4 and execute the exhibition action after locking piece 14 unblock, make child can see toy car 1000 directly perceivedly and just produced the action after walking a period, rather than just producing the action at present of toy car 1000 walking, the novelty of toy car 1000 has been increased on the one hand, on the other hand also makes this toy car 1000 just move after pulling open appropriate distance with the departure point, reduce action 4 and injure the possibility of staying the child at the departure point. And action pieces 4 are added, so that the toy car 1000 has the appearance transformation capability or the attack capability, and the overall interest and the visual impact effect of the toy car 1000 are enhanced.

In some embodiments, as shown in fig. 3-5, the road wheels 3 include a drive wheel 31 and a driven wheel 32, with the first engagement member 11 being connected to the driven wheel 32. Thus, the first engaging member 11 is not rotated when the driving wheel 31 is driven, and the locking member 14 is unlocked only when the toy vehicle 1000 actually walks on the ground, thereby improving the play effect of the toy vehicle 1000. In some embodiments, the travel wheels 3 of the toy vehicle 1000 may be only driven wheels 32, with the first engagement member 11 coupled to the driven wheels 32.

Also, in some embodiments, the first engaging member 11 is horizontally disposed, and the first engaging member 11 is movable between an upper stop position where the first engaging member 11 is engaged with the second engaging member 12 and a lower stop position where the first engaging member 11 is disengaged from the second engaging member 12. In this embodiment, the first engaging member 11 is connected to the driven wheel 32 instead of the driving wheel 31, so that the driving wheel 31 is prevented from being affected by the power device, the safety of the toy vehicle 1000 can be improved, and the axle 30 of the driven wheel 32 is movably disposed up and down without affecting the function of the driven wheel 32.

In the embodiment of the present invention, the locking member 14 is used to lock the action member 4 at the initial position of the movement, i.e. to ensure that the position of the action member 4 will not change when the state is not triggered, and the action member is in the fixed state, so as to avoid the uncontrolled random movement of the action member 4. The unlocking piece 13 is matched with the locking piece 14, and the unlocking piece 13 is triggered to unlock the locking piece 14, so that the locking piece 14 releases the action piece 4, and the action piece 4 is unfolded or thrown out. In this way, the locking member 14 and the unlocking member 13 ensure that the operating member 4 is triggered to expand or disengage only when the running wheels 3 are rotated according to a set condition, thereby achieving reliable control of the operating member 4.

In the embodiment of the present invention, the operation member 4 is provided on the vehicle body 2 in a foldable manner, for example, the operation member 4 can be changed from a folded state to an unfolded state. Alternatively, the operating element 4 may be detachably provided on the vehicle body 2, for example, the operating element 4 may be thrown out of the vehicle body 2. Here, the manner of installing the actuator 4 on the vehicle body 2 and the manner of triggering the deployment or throwing-out of the actuator 4 are various.

In some embodiments, the actuator 4 is slidably coupled to the body 2 such that when the actuator 4 is triggered to release the restraint, the actuator 4 slides out of the body 2 under the force of a spring or other force during travel of the toy vehicle 1000.

In some embodiments, the action member 4 is connected to the vehicle body 2 by a rope, and after the action member 4 is triggered to release the restriction, the action member 4 is thrown out of the vehicle body 2 and maintains the connection with the vehicle body 2 by the rope during the running of the toy vehicle 1000.

In other embodiments, after the operating member 4 slides out or is thrown away from the vehicle body 2, there is no connection between the operating member 4 and the vehicle body 2. Optionally, the actuator 4 is an ejector that is actuated by the actuator drive member 5 to eject it from the toy vehicle 1000 when unlocked. At this time, the ejection piece is similar to a shot which is emitted, the attack distance is long, and the toy car 1000 triggered by movement has strong fighting aggressivity with other toys.

In some embodiments, the actuation member 4 is pivotally attached to the body 2 such that when the actuation member 4 is unlocked, the actuation member 4 pivots out of the body 2 under the force of gravity, catapult force, or other forces during travel of the toy vehicle 1000.

Specifically, as shown in fig. 4 and 5, when the operating member 4 is rotatably connected to the vehicle body 2, the operating driving member 5 is a torsion spring connected to the operating member 4, so that when the operating member 4 is unlocked, the operating member 4 is rapidly opened by the action of the torsion spring.

In some embodiments, as shown in fig. 4 and 5, the actuating member 4 is a flap 41 rotatably disposed at the bottom of the body 2, and the flap 41 is released to actuate the actuating member 5 to rotate to contact the ground to turn the toy vehicle 1000. In the process that toy car 1000 traveles like this, toy car 1000 makes flap 41 be unlocked because of the driving of walking wheel 3 to toy car 1000 can vacate the sky and overturn, and is interesting very strong.

In some embodiments, as shown in fig. 6-8, the actuating member 4 is a plurality of extending members 42, and each of the extending members 42 is locked by the motion-activated assembly 1. In this way, in the process of driving the toy vehicle 1000, the unfolding parts 42 of the toy vehicle 1000 are unlocked due to the driving of the road wheels 3, so that the toy vehicle 1000 can unfold the plurality of unfolding parts 42, and the visual perception is more shocking.

Alternatively, the motion trigger assembly 1 locks only some of the deployment members 42, and the rest of the deployment members 42 are locked by the other deployment members 42, and the motion driving member 5 drives the deployment of the deployment members 42 when the deployment members 42 are unlocked to deform the toy vehicle 1000. Thus, the spreading member 42 of the toy car 1000 can be gradually spread layer by layer, and the ornamental value is high.

In one specific example, as shown in fig. 10 and 11, a coin holding portion 6 for holding or sucking a toy coin 200 is provided on a toy car 1000, and the toy car 1000 can be driven by holding a coin during play. When the coin holder 6 can hold the toy coin 200, the coin holder 6 can hold the toy coin 200 when the toy coin 200 is shot into the toy vehicle 1000.

Optionally, the action member 4 includes a coin-ejecting member (not shown) for driving the toy coin 200 out of the coin holding portion 6, and ejecting the toy coin 200. Therefore, the toy car 1000 can absorb coins and shoot the coins, reciprocating interaction action can be formed between the toy car 1000, and interestingness is strong.

The structure and play of three embodiments of toy vehicle 1000 are described below with reference to the drawings.

Example 1

Fig. 3-8 illustrate the configuration of the motion activated toy vehicle 1000 of example 1.

As shown in fig. 3 and 4, the motion-triggered toy vehicle 1000 is a transformable vehicle, which includes a vehicle body 2 and an action member 4, wherein the vehicle body 2 is a chassis, and the action member 4 includes a plurality of unfolding members 41 and is assembled into a body of the transformable vehicle. The deformable vehicle further comprises a front wheel and a rear wheel, a spring tooth box 71 is further arranged in the deformable vehicle, and the spring tooth box 71 is connected with the rear wheel. The front wheels are driven wheels 32, and the rear wheels are driving wheels 31. The bottom of the deformable wagon also comprises a flap 41. As shown in fig. 6, the plurality of spreaders 41 are divided into three parts, i.e., left, middle, and right, and the middle spreader 42 is connected to the vehicle body 2 via a connecting rod 44. As shown in fig. 7 and 8, the locking member 14 has locking hooks 141 on both upper and lower sides, the upper locking hook 141 is used for being clamped on the hook 421 on the unfolding member 42, and the lower locking hook 141 is used for being clamped on the flap 41. The upper latch hook 141 is latched to the middle spreading member 42, and the left and right spreading members 42 are latched by the middle spreading member 42.

The deformation vehicle slides backwards on a table top or a floor, so that the spring gear box 71 winds up, and after hands are loosened, the spring gear box 71 drives the rear wheel to rotate, so that the whole deformation vehicle runs forwards on the table top. In the process that the deformable vehicle runs forwards, the front wheel is lifted upwards, the front wheel is driven to rotate by the friction of the table top, the worm rotates synchronously with the front wheel, and the worm further drives the worm wheel and the eccentric wheel to rotate. When the eccentric is rotated to a position where its projection 131 faces the locking member 14, the locking member 14 is pushed backward.

After the lock 14 is translated backwards, the flap 41 is unlatched and the flap 41 is flipped under the force of the torsion spring. The whole deformation vehicle turns 360 degrees under the action of the turning plate 41.

The rearward translation of the locking member 14 unlocks both the intermediate deployment member 42 and the connecting rod 44, and the intermediate deployment member 42 and the connecting rod 44 rotate angularly open under the force of the torsion spring.

The middle spreading member 42 rotates by an angle to unlock the spreading members 42 at the left and right sides, and the spreading members 42 at the left and right sides respectively rotate by an angle outward under the action of the torsion spring to form the outward-opened shapes of the spreading members 42 at the left and right sides. The transformable vehicle is combined with the whole transformable vehicle, the transformable vehicle forms an animal to stand, and a winged state is formed.

Example 2

Fig. 9-11 and fig. 1 and 2 show the structure of a motion-triggered toy vehicle 1000 according to example 2.

As shown in fig. 9-11, the motion-triggered toy vehicle 1000 is a money-attracting transformation vehicle, the money-attracting transformation vehicle includes a vehicle body 2 and an action member 4, the vehicle body 2 is a chassis, and the action member 4 includes an unfolding member 41 and a turning plate 41 arranged at the bottom of the chassis.

The front end of the chassis is provided with a coin holding port, the front end of the chassis is also provided with a coin holding part 6, and the coin holding part 6 comprises a magnetic part 61 capable of holding the toy coin 200 and a coin clamping part 62 capable of clamping the toy coin 200.

The coin absorbing deformation vehicle also comprises a front wheel and a rear wheel, and the front wheel and the rear wheel are driven wheels 32. The locking element 14 is provided with a locking hook 141 on the underside for latching on the flap 41.

The coin absorbing deformation vehicle drives the inner wheel shaft 30 to rotate through rotation of the front wheel, so that the worm is driven to rotate, the worm drives the worm wheel to rotate, the eccentric wheel coaxially arranged with the worm wheel drives the locking piece 14 to unlock, the lower side lock hook 141 releases the turning plate 41, the turning plate 41 overturns under the action of the torsion spring, and the whole coin absorbing deformation vehicle overturns for 360 degrees under the action of the turning plate 41.

The chassis is internally provided with a magnetic part 61, a worm and a worm wheel, wherein the magnetic part 61 is used for adsorbing the toy coin 200, so that the toy coin 200 can be firmly adsorbed on the transformable vehicle, and the transformable vehicle can not fall off when being overturned in the air. The worm is provided on the wheel shaft 30 of the front wheel, and in the state of fig. 10, when the front wheel of the vehicle does not land, the wheel shaft 30 of the front wheel is deviated downward from the worm wheel by its own weight and does not mesh with the worm wheel. When the front wheel is grounded, the wheel shaft 30 of the front wheel is driven to move upwards to be meshed with the worm wheel, and the rolling of the front wheel drives the worm wheel to rotate.

The worm wheel is an incomplete worm wheel, namely teeth do not encircle a circle and only partially, an eccentric wheel is arranged below the worm wheel, and when the worm drives the worm wheel to rotate, the eccentric wheel synchronously rotates.

This worm wheel passes through fixed axle 19 and rotationally installs on the vehicle bottom dish, is equipped with a torsional spring (rotating the piece that resets 15 promptly) between worm wheel and vehicle bottom dish, and the effect of this torsional spring is that after worm wheel 1 took place to rotate under the worm drives, this worm wheel 1 can reset under the effect of torsional spring. When the worm wheel is reset, the protrusion 131 of the eccentric wheel is facing forward, and the eccentric wheel does not push the locking member 14 backward, i.e. the locking member 14 is in the locking position.

In the locked position, when the wheel axle 30 of the front wheel moves upwards to engage the worm with the worm wheel, the worm can drive the worm wheel to rotate, the worm wheel rotates and simultaneously drives the eccentric wheel to deflect, the convex edge of the eccentric wheel turns to the rear, so that the locking piece 14 is driven to move backwards, the locking piece 14 is unlocked from the bottom turning plate 41, and the backward movement of the locking piece 14 drives the unlocking of the upper unfolding piece 42, so that the vehicle body deforms. Then, when the child picks up the toy car 1000, the wheel shaft 30 of the front wheel moves down again, and the worm wheel returns to the locked position under the action of the torsion spring.

As shown in fig. 11, when the flap 41 is turned over, the flap 41 unlocks the bill clamping member 62. That is, the front coin clamping piece 62 is not used after the turning plate 41 is unlocked, the front coin clamping piece 62 is also unlocked after the turning plate 41 is unlocked, and the front end of the coin clamping piece 62 rotates upwards and clamps the toy coin 200.

Example 3

Fig. 12-14 illustrate the configuration of the motion activated toy vehicle 1000 of example 3.

The motion-triggered toy vehicle 1000 is a transformable vehicle, and the structural principle of the transformation triggering is basically the same as that of embodiment 2, and the description thereof is omitted. What is different is that, as shown in fig. 13 and 14, the vehicle body 2 is provided with a flange 21, and the second engaging member 12 is provided with a stopper 17 for limiting the rotation angle.

In order to prevent that the handheld car that warp of child from pulling backward, lead to the mistake to touch because of the front wheel lands under the state of coming, make the car that warp and get to child's hand, so set up stopper 17 on the worm wheel, this stopper 17 stretches into on the chassis downwards, cooperate with a chimb 21 of chassis rear end, thereby inject stopper 17 anticlockwise rotation, when the front wheel moves backward promptly, can drive worm wheel anticlockwise rotation, but because chimb 21 is to stopper 17's injecion, so the worm wheel can't take place to rotate, thereby avoid the bulge 131 of eccentric wheel to rotate the rear and trigger locking piece 14 unblock.

Of course, the anti-malfunction structure can be used in the above two embodiments, and can also be adapted to toy vehicles 1000 with different shapes and functions.

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 present 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 (9)

1. A motion-triggered toy vehicle, comprising:

a vehicle body;

a road wheel comprising a driven wheel;

the action piece is movably or flyably arranged on the vehicle body;

a motion trigger assembly, the motion trigger assembly comprising:

the first meshing component is connected with the driven wheel;

the second meshing part is driven by the first meshing part to rotate when meshed with the first meshing part;

the unlocking piece is connected with the second meshing piece so as to be driven by the second meshing piece to rotate;

the locking piece is movable between a locking position and an unlocking position, the locking piece is configured to be always kept at the locking position, the unlocking piece can push the locking piece to move towards the unlocking position when being rotated, the locking piece locks the action piece when at the locking position, and the locking piece releases the action piece when at the unlocking position;

the action driving piece is matched with the action piece and used for driving the action piece to move or fly away from the vehicle body when the action piece is released.

2. The motion activated toy vehicle of claim 1, wherein the first engagement member is a worm, the second engagement member is a worm gear, and the unlocking member is an eccentric.

3. The motion activated toy vehicle of claim 1, wherein the motion activation assembly further comprises: and the rotating reset piece is used for driving the second engagement piece to rotate to an initial angle, and the rotating reset piece is connected to the second engagement piece or the unlocking piece.

4. The motion activated toy vehicle of claim 3, wherein the unlocking member is coaxially coupled to the second engagement member, and the rotational return member is a torsion spring and is coaxially disposed on the unlocking member.

5. The motion-activated toy vehicle of claim 1, wherein the first engagement member is horizontally disposed on the body, the first engagement member being movable between an upper stop at which the first engagement member engages the second engagement member and a lower stop at which the first engagement member disengages the second engagement member.

6. The motion activated toy vehicle of claim 1, wherein the second engaging member or the unlocking member is provided with a stopper, and the body is provided with a flange for limiting a rotation angle of the stopper.

7. The motion activated toy vehicle of any one of claims 1-6, wherein the action member is a flap rotatably disposed on the bottom of the vehicle body, the flap being released such that the action drive member drives the flap to rotationally contact the ground to allow the toy vehicle to empty and turn.

8. The motion-activated toy vehicle of any one of claims 1-6, wherein the actuation member is a plurality of deployment members, each of the plurality of deployment members being secured by the motion-activated assembly, or the motion-activated assembly securing only some of the deployment members and remaining ones of the deployment members being secured by others of the deployment members, the actuation member actuating the deployment of the deployment members to deform the toy vehicle when the deployment members are unlocked.

9. The motion activated toy vehicle of any one of claims 1-6, having a coin holder thereon for holding or attracting a toy coin.

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