CN110711391A - Acceleration toy system - Google Patents

Abstract

The invention discloses an accelerating toy system, comprising: a toy; the driving and launching mechanism is used for accelerating and driving the toy and launching the toy; and the driving wheel is connected to the toy and is used for being driven by the driving and launching mechanism to rotate so as to drive the toy to move. According to the acceleration toy system provided by the embodiment of the invention, the toy and the driving launching mechanism form a system, driving force can be input to the toy through the driving launching mechanism during playing, and the driving force is input to the driving wheels of the toy instead of only pushing and bouncing the toy body. Therefore, the effect that the toy actively runs after being accelerated can be created, and the toy is not flicked passively. Compared with the playing method that the toy is bounced open, the driving wheel actively drives, so that the toy is more stable and durable in driving and stronger in operability.

Description

Acceleration toy system

Technical Field

The invention relates to the technical field of toys, in particular to an acceleration toy system.

Background

If the existing mainstream toy is not provided with a power mechanism or an accelerating device, the toy is mainly continued to sail by pushing or dialing by hands, the interestingness is low, and the user experience is poor.

Disclosure of Invention

The present invention is directed to solving at least one of the problems of the prior art. Therefore, the invention provides an accelerating toy system which can provide driving force for storage and navigation for a toy.

An acceleration toy system according to an embodiment of the present invention includes: a toy; the driving and launching mechanism is used for accelerating and driving the toy and launching the toy; and the driving wheel is connected to the toy and is used for being driven by the driving and launching mechanism to rotate so as to drive the toy to move.

According to the acceleration toy system provided by the embodiment of the invention, the toy and the driving launching mechanism form a system, driving force can be input to the toy through the driving launching mechanism during playing, and the driving force is input to the driving wheels of the toy instead of only pushing and bouncing the toy. Therefore, the effect that the toy actively runs after being accelerated can be created, and the toy is not flicked passively. Compared with the playing method that the toy is bounced open, the driving wheel actively drives, so that the toy is more stable and durable in driving and stronger in operability.

In some embodiments, the drive launching mechanism has: a holder for cooperating with the toy to transmit the driving force of the driving transmission mechanism to the driving wheel; and the driving piece is used for outputting driving force and transmitting the driving force to the driving wheel so as to accelerate the driving wheel to rotate.

Specifically, the toy has: and the locking piece is used for being matched with the retaining piece so that the driving wheel can receive the driving force output by the driving piece.

Optionally, the locking member and the holding member are engaged by means of clamping, inserting or magnetic attraction.

Further, the drive transmission mechanism has: the operating piece is manually operated to enable the driving piece to generate driving force.

In some embodiments, the driver comprises: the source wheel is matched with the operating part and is rotated by manually operating the operating part; the driving wheel is connected with the source head wheel to realize driving force transmission; and the driven driving wheel is respectively connected with the driving wheel and the driving wheel of the toy so as to realize that the driving force is output to the driving wheel.

Specifically, the driving member further includes: the clutch wheel is driven by the driving wheel to be connected between the driving wheel and the driven driving wheel when the driving wheel rotates towards the first direction, and the clutch wheel is driven to be separated from the driven driving wheel when the driving wheel rotates towards the second direction.

In some embodiments, the drive launching mechanism has: and the unlocking piece is used for unlocking the toy from the holder so as to enable the toy to move under the driving of the driving wheel.

In some alternative embodiments, the unlocking member includes: the ejector pin is used for ejecting the toy away from the driving and launching mechanism when the toy is extended out; the swinging piece is used for controlling the extension and/or retraction of the thimble; the triggering piece is used for driving the swinging piece to swing when being triggered.

In some alternative embodiments, the drive launching mechanism has: and the ejection piece is used for ejecting the toy away from the driving and launching mechanism while the unlocking piece unlocks the toy.

Specifically, the ejector includes: a slide bar for locking onto the holder, the slide bar disengaging from the holder when the unlocking member is activated; and the ejection elastic piece is used for driving the holding piece towards the ejection direction.

In some embodiments, the toy has: the driving connecting piece is matched with the driving transmitting mechanism so as to receive the driving force output by the driving transmitting mechanism; and the transmission part is used for transmitting the driving force received by the driving connecting part to the driving wheel.

In some embodiments, the acceleration toy system further comprises: and the energy storage part is arranged on the toy and/or the driving launching mechanism, is used for storing energy while the driving launching mechanism outputs driving force, and further drives the driving wheel to rotate when the energy storage part releases energy.

In some embodiments, the acceleration toy system further comprises: a playing field for the toy to move therein for competition or competition.

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 an acceleration toy system according to one embodiment of the present invention;

FIG. 2 is a sectional view showing the internal structure of the driving transmission mechanism in one embodiment of the present invention;

FIG. 3 is a schematic perspective view of a portion of the driving launching mechanism in the embodiment of FIG. 1;

FIG. 4 is a schematic diagram of a partially exploded view of the driving and launching mechanism of the embodiment of FIG. 1;

FIG. 5 is a schematic diagram of a partially exploded configuration of a driving firing mechanism in accordance with another embodiment of the present invention;

FIG. 6 is an exploded perspective view of the toy of the embodiment of FIG. 1;

FIG. 7 is a perspective view of a portion of the toy of the embodiment of FIG. 1;

FIG. 8 is a schematic view of an acceleration toy system according to another embodiment of the present invention;

FIG. 9 is a schematic perspective view of a portion of the driving launching mechanism in the embodiment of FIG. 8;

figure 10 is an exploded view of a portion of the structure of the toy of the embodiment of figure 8;

FIG. 11 is a perspective view of the toy of the embodiment of FIG. 8;

figure 12 is a schematic view of an accelerating toy system with a playing field.

Reference numerals:

an acceleration toy system 1000,

A toy 200,

A main body 210, a driving wheel 211,

The driving connection member 230, the input disc 231, the input hole 231a, the locking member 232, the locking barrel 2321, the limiting groove 2322, the transmission member 240, the flywheel gear 241, the driving gear 242, the intermediate gear 243, the locking member,

An energy storage component 01,

A drive transmission mechanism 100,

A base body 110, an emitting opening 110a, a push limiting groove 110b, a stroke limiting groove 110c, a mounting hole 110d,

A holding piece 120, a holding tube 121, a limit block 1211, a bayonet 121a, a card slot 121b, a clamping piece 122, a torsion spring 123,

A rotary drive member 130,

A rotating body 131, a transmission shaft 1311, a transmission end tooth 1312, a connecting part 1313,

Push-pull rod 132, push rod portion 1321, rotary disc 1322, link portion 1323,

A driving member 140, a source wheel 141, an active driving wheel 143, a passive driving wheel 146, a clutch wheel 144, a fixed gear 1441, a skip gear 1442,

An operating member 142,

Unlocking piece 150, trigger piece 154, thimble 155, swinging piece 156, extension plate 1541,

The ejection member 150a, the sliding rod 151, the sliding hole 1511, the elastic reset member 1512, the ejection elastic member 152, the push plate 153, the transverse push rod 1531, the limit push block 1532, the jump ring groove 1532a, and the elastic reset member,

A playing field 300.

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.

An acceleration toy system 1000 according to an embodiment of the present invention is described below with reference to the drawings.

An accelerating toy system 1000 according to an embodiment of the present invention, as shown in fig. 1 and 8, includes: a toy 200, a drive launching mechanism 100, and a driving wheel 211, the drive launching mechanism 100 for accelerating the toy 200 and launching the toy 200. The driving wheel 211 is connected to the toy 200, and the driving wheel 211 is driven by the driving and launching mechanism 100 to rotate so as to drive the toy 200 to move.

The toy 200 and the driving transmission mechanism 100 are formed into a system which can input a driving force to the toy 200 through the driving transmission mechanism 100 when playing, and the driving force is input to the driving wheels 211 of the toy 200, rather than just directly pushing or bouncing the body 210 of the toy 200. This creates the effect of the toy 200 actively traveling after acceleration as if the toy 200 had its own motor. The driving force is finally applied to the driving wheel 211, and compared with the playing method that the toy is bounced open, the accelerating mode that the driving wheel 211 actively runs enables the toy 200 to run more stably and durably, the running speed is stable, and the toy can be conveniently tracked by children of a low age, so that the toy 200 is stronger in operability.

Because the driving wheel 211 of the toy 200 can obtain higher speed and run for a long time, the toy 200 can be tested in various places such as climbing, winding for many circles, leaping and the like, and has more impact and strong interest in vision.

In some embodiments, the drive launching mechanism 100 has: a holder 120 and a driver 140. The holder 120 is adapted to cooperate with the toy 200 to transmit the driving force of the driving transmission mechanism 100 to the driving wheel 211. That is, the holder 120 functions to maintain the driving launching mechanism 100 in a state of being coupled to the toy 200, so that the toy 200 is not automatically separated from the driving launching mechanism 100 even if the driving wheel 211 is rotated on the toy 200 during the transmission of the driving force.

The driving member 140 is used for outputting a driving force and transmitting the driving force to the driving wheel 211 so as to accelerate the rotation of the driving wheel 211, i.e. the driving member 140 provides a power source for the running of the toy 200.

Specifically, as shown in fig. 6, 7, 10 and 11, toy 200 has a locker 232, and locker 232 is adapted to cooperate with holder 120 so that driver 211 can receive the driving force output from driving member 140.

That is, retaining member 120 is the structure on drive launching mechanism 100 for engaging toy 200, and retaining member 232 is the structure on toy 200 for engaging drive launching mechanism 100, either in the same system or only one. Even if retainer 120 and retaining member 232 are eliminated from the same system, acceleration toy system 1000 may utilize other means to maintain the engagement of the two. For example, toy 200 may be coupled to the top of drive launching mechanism 100 with driver 211 off the ground and toy 200 held on drive launching mechanism 100 by gravity.

Optionally, retaining member 232 and retaining member 120 are engaged by a snap-fit or bayonet-type or magnetically-attached connection, such that retaining member 232 is easily aligned when engaged with retaining member 120, and retaining member 232 is easily disengaged from retaining member 120 and is not easily locked. Of course, depending on the actual production, other combinations are possible, such as the retaining member 120 being a movable pin connected to an electrically controlled valve, which when combined electrically controls the insertion of the movable pin on the toy 200.

In the embodiment of the present invention, the driving transmission mechanism 100 has a base 110, and the holder 120 is provided on the base 110.

In some embodiments, as shown in fig. 2, a retaining member 120 is movably disposed on the base 110 between a locked position, in which the retaining member 120 is configured to secure the toy 200, and a released position, in which the retaining member 120 releases the toy 200. Since the holder 120 can be switched between the locking position and the releasing position, and has the function of fixing and releasing the toy 200 at two positions, when the switching time of the two positions is short and the speed is fast, the effect of launching the toy 200 on the driving launching mechanism 100 is ensured.

In some embodiments, as shown in fig. 2, the drive launching mechanism 100 has: and an unlocking member 150 for disengaging the toy 200 from the holder 120 so that the toy 200 moves by the driving wheel 211. The presence of the unlocking member 150 may achieve the goal of an operator in accurately controlling the launching of the toy 200.

Alternatively, as shown in fig. 2, the holder 120 includes: the clamping piece 122 is used for being clamped on the toy 200, the clamping piece 122 is matched with the unlocking piece 150, and when the unlocking piece 150 is triggered, the clamping piece 122 is driven to release clamping on the toy 200. That is, the unlocking member 150 makes the holder 120 in the locked position, and when the toy 200 is fitted on the holder 120, the catching member 122 catches on the toy 200, achieving a reliable combination of the holder 120 and the toy 200. When the unlocking member 150 is triggered, the retaining member 120 is in the release position, and at the same time the catch member 122 is able to disengage from the catch with the toy 200, so that the toy 200 is disengaged from the retaining member 120 and the toy 200 is ejected from the drive-launching mechanism 100.

Alternatively, as shown in fig. 2, the base 110 has a launching port 110a, and the driving launching mechanism 100 can be coupled to the toy 200 through the launching port 110 a. The power output end of driving member 140 is located in base 110 and has one end disposed opposite to emitting opening 110a, in this way, it is advantageous to combine with toy 200.

As shown in fig. 2, the retaining member 120 is disposed in the base 110, and a portion of the retaining member 120 protrudes from the emitting opening 110a at the releasing position, that is, the retaining member 120 can generate a displacement along the emitting opening 110a when releasing, so that the movement of the retaining member 120 can simultaneously move the toy 200, thereby achieving the emitting effect. When the locking position is in which the clamping member 122 abuts against the inner wall of the transmitting opening 110a to be clamped on the toy 200, and when the releasing position is in which the clamping member 122 at least partially extends out of the transmitting opening 110a to be disengaged from the toy 200, it can be understood that the inner wall of the transmitting opening 110a plays a role in limiting the clamping member 122, and when the clamping member 122 is located in the transmitting opening 110a, the clamping member 122 is clamped on the toy 200 through the abutting effect of the inner wall of the transmitting opening 110 a; when the portion of the clip 122 protrudes out of the transmission opening 110a, the protruding portion of the clip 122 is removed from the restriction, thereby being out of the clip with the toy 200. In this way, the clamping piece 122 is matched with the transmitting port 110a to realize clamping, the structure is simple, and the clamping is more convenient.

In some embodiments, as shown in fig. 3 and 5, the output of the driving member 140 can be driven in a linear direction or a rotational direction. The power take off component of the driver 140 is referred to herein as the rotary driver 130.

In some embodiments, as shown in fig. 3 and 4, the rotary driving member 130 is a rotator 131 rotatably disposed on the base 110, so that the driving wheel 211 of the toy 200 is rotated by the rotation of the rotator 131.

Alternatively, as shown in fig. 3 and 4, the rotating body 131 includes a transmission shaft 1311, transmission end teeth 1312 disposed at both ends of the transmission shaft 1311, and a connection portion 1313, wherein the transmission end teeth 1312 may be connected to the driving member 140 by gear engagement, so that the driving member 140 can drive the transmission end teeth 1312 to rotate. The driving wheel 211 of the toy 200 may be connected with a bevel gear set, and the connecting portion 1313 may be matched with an input gear of the bevel gear set in a spline matching manner to drive the driving wheel 211 to rotate; alternatively, the connecting portion 1313 may be engaged with an input gear of the bevel gear set to drive the driving wheel 211 to rotate.

As shown in fig. 3, the holder 120 includes: the holding cylinder 121, the holding cylinder 121 is set around the rotating body 131, one end of the rotating body 131 extends out of the holding cylinder 121 and is connected with the driving member 140, because the rotating body 131 drives the driving wheel 211 on the toy 200 to rotate through rotation, in this way, after the holding cylinder 121 is fixed with the toy 200, the other end of the rotating body 131 is positioned in the holding cylinder 121. The unlocking member 150 is attached to the holding cylinder 121, which facilitates unlocking of the toy 200 when the holding cylinder 121 and the toy 200 are fixed.

Optionally, as shown in fig. 4, the outer wall of the holding cylinder 121 is provided with a distance limiting block 1211 distributed along the axial direction, the inner wall of the transmitting opening 110a is provided with a distance limiting groove 110c, and the distance limiting block 1211 and the distance limiting groove 110c are matched to provide a guiding function for the holding cylinder 121 to extend out of the transmitting opening 110a, so as to ensure that the holding cylinder 121 moves reliably between the locking position and the releasing position.

Optionally, as shown in fig. 3 and 4, a bayonet 121a penetrating in the thickness direction is disposed on the wall of the holding cylinder 121, the holding part 120 further includes a clamping member 122 rotatably disposed in the bayonet 121a, a chuck of the clamping member 122 extends into the holding cylinder 121 through the bayonet 121a to be clamped on the toy 200, and a torsion spring 123 for driving the clamping member 122 to exit from the bayonet 121a is connected to a rotating shaft of the clamping member 122. That is, when the toy 200 is engaged with the holding cylinder 121 and the holding cylinder 121 is pushed to move to the locking position, the engaging member 122 is driven to rotate in the engaging opening 121a toward the inner side of the holding cylinder 121 due to the inner wall of the launching opening 110a, and the torsion spring 123 is compressed, thereby engaging the toy 200; when the toy 200 is unlocked, the toy 200 and the retaining cylinder 121 move to the release position, the torsion spring 123 plays a role in resetting, and when the part of the clamping piece 122 extends out of the transmitting opening 110a, the clamping piece 122 rotates and exits from the bayonet 121a, so that the toy 200 and the retaining cylinder 121 are separated and released. The launching mechanism 100 is driven in this way to lock and release the toy 200 more easily, and the operation is more convenient.

In some embodiments, as shown in fig. 5, the rotary driving member 130 is a push-pull rod 132 disposed on the base 110 in a reciprocating manner, the holding member 120 is provided with a through hole for the push-pull rod 132 to extend out of the base 110, the outer end of the push-pull rod 132 is engaged with the toy 200, and the driving member 140 drives the push-pull rod 132 to move back and forth so that the push-pull rod 132 drives the driving wheel 211 of the toy 200 to rotate. That is, the rotary driving member 130 can drive the driving wheel 211 of the toy 200 to rotate by pushing and pulling back and forth, for example, the push-pull rod 132 is formed as a push-pull rack, and the driving wheel 211 of the toy 200 is connected with a gear set, so that the driving wheel 211 can be driven to rotate continuously by the engagement of the rack and the gear when the push-pull rod 132 is pushed and pulled back and forth out of the through opening of the holding member 120.

Alternatively, as shown in fig. 5, the push-pull rod 132 includes a push rod portion 1321, a rotating disc 1322, and a link portion 1323 having both ends pivotally provided on the push rod portion 1321 and the rotating disc 1322, respectively. The rotating disc 1322 is configured to be connected to the driving member 140 and can rotate under the driving of the driving member 140, so that when the rotating disc 1322 rotates, the pushing rod portion 1321 can be pushed and pulled back and forth by the action of the connecting rod portion 1323. The push-pull rack is formed on the push-rod portion 1321, and thus the driving wheel 211 of the toy 200 is driven to rotate.

In some embodiments, as shown in fig. 3 and 9, the drive firing mechanism 100 has: the operating member 142 is manually operated to generate a driving force for the driving member 140. Here, the operating member 142 may be variously formed, for example, the operating member 142 may be formed to directly output a rotational force by a crank, or output a rotational force by pulling, or the like.

In some embodiments, as shown in fig. 3, the drive member 140 includes: a source wheel 141, an active drive wheel 143, and a passive drive wheel 146. The source wheel 141 is engaged with the operating member 142, and the source wheel 141 is rotated by manually operating the operating member 142. The driving wheel 143 is connected to the source wheel 141 for driving force transmission, and the driven driving wheel 146 is connected to the driving wheel 143 and the driving wheel 211 of the toy 200, respectively, for driving force output to the driving wheel 211.

Specifically, the operating member 142 is a rack engaged with the source pulley 141 or a string wound around the source pulley 141. For example, when the operating member 142 is a rack, one end of the rack extends out of the base 110, and the other end of the rack is engaged with the source wheel 141, so that pulling the rack can rotate the source wheel 141, thereby providing a driving force. When the operating member 142 is a rope, one end of the rope extends out of the base 110, and the other end of the rope is wound on the source wheel 141, so that pulling the rope can also rotate the source wheel 141 to provide driving force. In the two modes, the driving member 140 has a simple structure, is convenient to operate and has stronger playability.

Specifically, as shown in fig. 3 and 4, the driving member 140 further includes: the clutch pulley 144 is configured to drive the clutch pulley 144 to be connected between the driving pulley 143 and the driven driving pulley 146 when the driving pulley 143 rotates in a first direction (e.g., clockwise in fig. 3), and to drive the clutch pulley 144 to be disconnected from the driven driving pulley 146 when the driving pulley 143 rotates in a second direction (e.g., counterclockwise in fig. 3). By means of the clutch wheel 144, the operating member 142 can be pulled back and forth to continuously accelerate the driven driving wheel 146, so that the rotary driving member 130 can be driven better.

For example, when the operating member 142 is a rack, the rack is drawn out from the base 110, the source wheel 141 rotates, and the driving wheel 143 is connected to and rotates the driven driving wheel 146 through the clutch wheel 144; the rack is pushed back into the base body 110, the source wheel 141 rotates reversely, the driving wheel 143 is separated from the driven driving wheel 146, the driven driving wheel 146 is not driven any more, and therefore continuous acceleration can be achieved through reciprocating pushing and pulling of the rack.

For example, when the operating member 142 is a rope, the active driving wheel 143 or the source wheel 141 may be provided with a return spring, the rope is pulled out from the base 110, the source wheel 141 rotates, and the active driving wheel 143 is connected to the passive driving wheel 146 through the clutch wheel 144 and rotates; after the rope is loosened and traction is lost, under the action of the return spring, the driving wheel 143 or the source head wheel 141 reversely rotates, the driving wheel 143 is separated from the driven driving wheel 146, and the rope is wound on the source head wheel 141 again, so that continuous acceleration can be realized by reciprocating pulling of the rope.

Alternatively, as shown in fig. 3 and 4, the clutch wheel 144 includes a fixed gear 1441 and a skip gear 1442, the fixed gear 1441 is coaxially connected to the driven driving wheel 146, the skip gear 1442 is movable in the axial direction of the fixed gear 1441, and the skip gear 1442 is configured to be engaged with or disengaged from the driving wheel 143 and the fixed gear 1441. The active driving wheel 143 and the passive driving wheel 146 can be separated or connected in this way, and the structure is simple and the use is more convenient.

In some alternative embodiments, as shown in fig. 9, the unlocking member 150 includes: a thimble 155 for ejecting the toy 200 away from the drive launching mechanism 100 when extended, a pendulum 156 for controlling the extension and/or retraction of the thimble 155, and a trigger 154 for driving the pendulum 156 to swing when triggered. That is, the trigger 154 is triggered to move, and drives the swing member 156 to swing so as to make the thimble 155 move in a telescopic manner, so that the thimble 155 pushes the toy 200 to separate from the driving and launching mechanism 100, thereby unlocking the driving and launching mechanism 100 and the toy 200.

Optionally, in the example of fig. 8, a magnetic attraction member (not shown) is disposed at a joint of the driving launching mechanism 100 and the toy 200, so that the thimble 155 is pushed to separate the magnetic attraction member from the thimble, which is simple in structure.

In some alternative embodiments, as shown in fig. 3 and 4, the drive launching mechanism 100 has: an ejector 150a for ejecting the toy 200 away from the driving launching mechanism 100 while the unlocking member 150 unlocks the toy 200. This springs toy 200 open, causing toy 200 to initially have a certain speed of travel.

Specifically, the ejector 150a includes: a sliding rod 151 and an ejection elastic member 152, wherein the sliding rod 151 is used for locking on the holding member 120, the sliding rod 151 is separated from the holding member 120 when the unlocking member 150 is triggered, and the ejection elastic member 152 is used for driving the holding member 120 towards the ejection direction, so that the ejection effect of the toy 200 and the holding member 120 is realized through the elastic action.

Optionally, as shown in fig. 3, a clamping groove 121b is formed in the holding cylinder 121, and one end of the sliding rod 151 is fitted to the clamping groove 121b during locking, so that the sliding rod 151 is engaged with and disengaged from the clamping groove 121b to lock and unlock the holding cylinder 121 by the sliding rod 151.

Optionally, as shown in fig. 3, the other end of the sliding rod 151 is provided with a sliding hole 1511, the unlocking member 150 further includes a depressible trigger 154, the trigger 154 is provided with an inclined extension plate 1541, and the extension plate 1541 is fitted on the sliding hole 1511, so that the extension plate 1541 can drive the sliding rod 151 to slide during the pressing movement with the trigger 154, thereby unlocking the retainer 120. As shown in fig. 2, the base 110 is provided with a mounting hole 110d, the trigger 154 is fitted in the mounting hole 110d, and the mounting hole 110d is used for guiding the trigger 154 and ensuring a smooth pressing process of the trigger 154.

Optionally, as shown in fig. 3, an elastic reset member 1512 is disposed on the sliding rod 151, and one end of the elastic reset member 1512 is connected to the sliding rod 151 and the other end is connected to the base 110, so that when the pressing on the trigger 154 is removed, the sliding rod 151 can be reset to the locking position. In a specific example, the elastic restoring member 1512 is a spring or an elastic rope, but the elastic restoring member 1512 is not limited thereto and will not be described in detail here.

Optionally, as shown in fig. 3, a limited push groove 110b is formed in the base 110, and the unlocking member 150 further includes: a push plate 153 located between the holder 120 and the ejection spring 152. The push plate 153 includes: a lateral push rod 1531 and a limit push block 1532. The transverse pushing rod 1531 extends along the moving direction of the holding member 120 and abuts against the holding member 120, since the ejection elastic member 152 is an elastic member, the direct contact with the holding member 120 is likely to cause working interference on the holding member 120, and the transverse pushing rod 1531 abuts against the holding member 120, which is not only beneficial to avoiding the interference condition, but also capable of reliably transmitting the elastic force of the ejection elastic member 152 to the holding member 120. The push stopper 1532 is located in the push restricting groove 110b to restrict a stroke by the push restricting groove 110b, and by restricting the stroke, it can be ensured that a part of the holder 120 protrudes from the emitting opening 110a rather than completely separating from the emitting opening 110a when the holder 120 is at the release position. One side of the limiting push block 1532 far away from the holding member 120 is opened to form a clamp spring groove 1532a, one end of the ejection elastic member 152 is matched with the clamp spring groove 1532a, and the other end of the ejection elastic member 152 is stopped against the inner wall of the limiting push groove 110b, so that the ejection elastic member 152 can be reliably positioned between the limiting push block 1532 and the limiting push groove 110b, and is not easy to fall off and separate, and the stable and reliable ejection process of the holding member 120 is ensured.

In some embodiments, as shown in fig. 6, 7 and 10, 11, toy 200 has: the driving connecting member 230 is used for cooperating with the driving launching mechanism 100 to receive the driving force output by the driving launching mechanism 100, and the transmission member 240 is used for transmitting the driving force received by the driving connecting member 230 to the driving wheel 211. Of course, in other embodiments, the driving link 230 may be disposed on the driving wheel 211, i.e. the driving launching mechanism 100 may also directly accelerate the driving wheel 211 without being driven by the transmission member 240.

In some embodiments, as shown in fig. 1 and 2, the driving link 230 includes an input disc 231 rotatably disposed on the body 210, and the driving transmission member 240 is used to rotate the driving wheel 211 by driving the input disc 231 to rotate after the driving launching mechanism 100 is engaged with the input disc 231. Alternatively, the driving connection member 230 includes an input bar (not shown) linearly movably disposed on the body 210, and after the driving launching mechanism 100 is combined with the input bar, the driving transmission member 240 is driven to rotate by driving the input bar to linearly move, for example, the input bar may be a rack, the transmission member 240 is a gear set, and the rack drives the energy storage member 01 to move by cooperating with the gear set.

Alternatively, as shown in fig. 1, 6 and 7, when the drive link 230 includes the input disc 231, the input disc 231 has an input hole 231a to be inserted into the input hole 231a from the output end of the drive transmitting mechanism 100, i.e., the input disc 231 and the output end of the drive transmitting mechanism 100 realize torque transmission therebetween in a plug-in fit manner through the input hole 231 a. Alternatively, the input plate 231 may have an input post (not shown) to receive an output end of the input post, and torque transmission may be achieved by coupling the input plate 231 to the output end of the drive-launching mechanism 100 via the input post. Alternatively, the input disc 231 may have a plurality of input pegs (not shown) for insertion by the output end between the plurality of input pegs, such that the input disc 231 and the output end of the drive launching mechanism 100 are torque-transferred by a snap-fit engagement via the input pegs. In this manner, the input disc 231 is easily and simply combined with the output end of the driving launching mechanism 100.

Optionally, when the input disc 231 is provided with the input hole 231a, the input hole 231a is a non-circular hole (not shown in the figure), and after the non-circular hole 231a is matched with the output end of the driving and transmitting mechanism 100, the input hole 231a and the output end can be in insertion fit, and the input disc 231 can be limited from rotating circumferentially relative to the output end, so that the input disc 231 and the output end can be combined stably and reliably. Or the inner wall of the input hole 231a is provided with a clamping groove and/or a clamping protrusion, for example, the input hole 231a is combined with the output end of the driving and launching mechanism 100 through the clamping groove, or the input hole 231a is combined with the output end of the driving and launching mechanism 100 through the clamping protrusion, or the input hole 231a is combined with the output end of the driving and launching mechanism 100 through the combined action of the clamping groove and the clamping protrusion, in such a way, the circumferential rotation of the input disc 231 relative to the output end is limited, and the combination is ensured to be reliable.

When the input disc 231 is provided with the input column, the input column is a non-cylindrical column, and after the non-cylindrical input column is matched with the output end of the driving emission mechanism 100, the non-cylindrical input column and the non-cylindrical input column can be sleeved, the input disc 231 can be limited from rotating circumferentially relative to the output end, and the combination of the input column and the non-cylindrical input column is stable and reliable. Or the outer wall of the input column is provided with a clamping groove and/or a clamping protrusion, and after the input column is combined with the output end of the driving emission mechanism 100, the input column can be limited to rotate circumferentially relative to the output end, so that reliable combination is ensured.

Alternatively, the input hole 231a other than the circular hole may be an inner hexagonal hole or an elliptical hole, so that stable torque transmission can be ensured after the input hole is combined with the output end of the driving transmission mechanism 100. Of course, the shape of the input hole 231a is not limited thereto, and thus, will not be described herein.

In some embodiments, as shown in fig. 2-4, the locking member 232 includes a locking barrel 2321 for housing the input disc 231 or the input bar, and the toy 200 can be sleeved on the driving launching mechanism 100 through the locking barrel 2321, so as to provide a good supporting function and ensure the reliable and stable operation of the input disc 231 or the input bar. At least one of a limiting groove 2322 and a limiting block (not shown) for being matched with the driving launching mechanism 100 is arranged on the locking cylinder 2321, so that the locking cylinder 2321 is limited to rotate circumferentially relative to the driving launching mechanism 100, and the stability of combination of the locking cylinder 2321 and the driving launching mechanism 100 is improved.

In some embodiments, the acceleration toy system 1000 further comprises: and the energy storage part 01 is arranged on the toy 200 and/or the driving launching mechanism 100 and is used for storing energy while driving the launching mechanism 100 to output driving force and further driving the driving wheel 211 to rotate when the energy storage part 01 releases energy.

When the energy storage member 01 is positioned on the drive launching mechanism 100, as shown in FIG. 3, the passive drive wheel 146 is coupled to the energy storage member 01, and both the energy storage member 01 and the drive member 140 are coupled. That is, when the passive driving wheel 146 and the rotary driving member 130 obtain higher kinetic energy, the kinetic energy of the passive driving wheel 146 and the rotary driving member 130 can be stored in the energy storage member 01 by being connected to the energy storage member 01, so that the passive driving wheel 146 and the rotary driving member 130 can continuously output the kinetic energy to the outside, which is beneficial to increase the driving time, the rotating speed of the wheels of the toy 200 transmitted by the driving transmission mechanism 100 can be maintained, the rotating speed is more durable, and the toy 200 can run farther.

As shown in fig. 6, when the energy storage element 01 is disposed on the toy 200, the energy storage element 01 is disposed on the body 210 and connected to the driving wheel 211, and the transmission element 240 is connected to the energy storage element 01 to drive the energy storage element 01 to store energy. The energy storage member 01 outputs power to the outside and makes the power more durable, so that the speed obtained by the driving wheels 211 is also more durable and the running distance of the toy 200 is longer.

Optionally, the energy storage member 01 is a flywheel or a coil spring. As shown in fig. 2, the energy storage member 01 is a flywheel, and the flywheel has a large mass and a large inertia effect, so that the flywheel can better store kinetic energy through rotation of the flywheel. The coil spring can realize the conversion between kinetic energy and elastic potential energy, and also can play a good energy storage role.

In some embodiments, as shown in fig. 12, the acceleration toy system 1000 further comprises: a playing field 300 for the toy 200 to move within for competition or fight. The field limitation can be increased, and the accelerated playing method can be fully developed.

Examples

A specific method of use of the present invention is described below in conjunction with fig. 1-4.

Step 1: the toy 200 is installed on the launching mechanism 100, and the pull rope handle is pulled out for many times, so that the flywheel built in the toy 200 rotates at a high speed to store energy.

The rope can be drawn out by pulling the pull ring of the pull rope outwards, and the rope drives the source head wheel 141 to rotate, so that the clutch wheel 144 is meshed with the driving wheel 143 and the driven driving wheel 146. When the pull ring of the pull rope is pulled to the end or loosened, the spring in the head pulley 141 can recover the rope to reset the pull ring, and the clutch pulley 144 and the driven driving pulley 146 are in a disengaged state. When the tab is pulled multiple times, the driven drive wheel 146 can be made to rotate at high speed.

The driving transmission mechanism 100 and the toy 200 are fastened together, the locking barrel 2321 is locked by the clamping member 122, so that the rotary driving member 130 is matched with the input disc 231 to drive the driving teeth 242 and the decelerating teeth 243 to drive the flywheel teeth 241 and the flywheel to rotate at a high speed for energy storage, and after the energy storage is carried out with the high-speed rotation of the flywheel, the flywheel teeth 241 drive the decelerating teeth and simultaneously drive the driving wheel 211 to drive forwards, so that the vehicle can run quickly and durably.

Step 2: pressing trigger 154 releases holder 120 and ejector 150a ejects holder 120, disengaging toy 200 from launching mechanism 100 and launching toy 200 onto the ground, a table, or a track.

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 (14)

1. An accelerating toy system, comprising:

a toy;

the driving and launching mechanism is used for accelerating and driving the toy and launching the toy;

and the driving wheel is connected to the toy and is used for being driven by the driving and launching mechanism to rotate so as to drive the toy to move.

2. The accelerating toy system of claim 1, wherein the drive launching mechanism has:

a holder for cooperating with the toy to transmit the driving force of the driving transmission mechanism to the driving wheel;

and the driving piece is used for outputting driving force and transmitting the driving force to the driving wheel so as to accelerate the driving wheel to rotate.

3. The accelerating toy system of claim 2, wherein the toy has:

and the locking piece is used for being matched with the retaining piece so that the driving wheel can receive the driving force output by the driving piece.

4. An accelerating toy system as set forth in claim 3, characterized in that the locking element cooperates with the holding element in a snap-fit or bayonet-fit or magnetically-attracted manner.

5. The accelerating toy system of claim 2, wherein the drive launching mechanism has:

the operating piece is manually operated to enable the driving piece to generate driving force.

6. The accelerating toy system of claim 5, wherein the drive member includes:

the source wheel is matched with the operating part and is rotated by manually operating the operating part;

the driving wheel is connected with the source head wheel to realize driving force transmission;

and the driven driving wheel is respectively connected with the driving wheel and the driving wheel of the toy so as to realize that the driving force is output to the driving wheel.

7. The accelerating toy system of claim 6, wherein the drive member further comprises:

the clutch wheel is driven by the driving wheel to be connected between the driving wheel and the driven driving wheel when the driving wheel rotates towards the first direction, and the clutch wheel is driven to be separated from the driven driving wheel when the driving wheel rotates towards the second direction.

8. The accelerating toy system of claim 2, wherein the drive launching mechanism has:

and the unlocking piece is used for unlocking the toy from the holder so as to enable the toy to move under the driving of the driving wheel.

9. The accelerating toy system of claim 8, wherein the unlocking member includes:

the ejector pin is used for ejecting the toy away from the driving and launching mechanism when the toy is extended out;

the swinging piece is used for controlling the extension and/or retraction of the thimble;

the triggering piece is used for driving the swinging piece to swing when being triggered.

10. The accelerating toy system of claim 8, wherein the drive launching mechanism has:

and the ejection piece is used for ejecting the toy away from the driving and launching mechanism while the unlocking piece unlocks the toy.

11. The accelerating toy system of claim 10, wherein the ejector includes:

a slide bar for locking onto the holder, the slide bar disengaging from the holder when the unlocking member is activated;

and the ejection elastic piece is used for driving the holding piece towards the ejection direction.

12. The accelerating toy system of claim 1, wherein the toy has:

the driving connecting piece is matched with the driving transmitting mechanism so as to receive the driving force output by the driving transmitting mechanism;

and the transmission part is used for transmitting the driving force received by the driving connecting part to the driving wheel.

13. An accelerating toy system as in any of claims 1-12, further comprising:

and the energy storage part is arranged on the toy and/or the driving launching mechanism, is used for storing energy while the driving launching mechanism outputs driving force, and further drives the driving wheel to rotate when the energy storage part releases energy.

14. An accelerating toy system as in any of claims 1-12, further comprising:

a playing field for the toy to move therein for competition or competition.

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