CN217041288U - Walking triggered rotary shooting toy - Google Patents

Abstract

The utility model discloses a but rotatory of walking trigger penetrates toy, include: the machine body is provided with traveling wheels; a rotating portion, comprising: the rotating body is rotatably connected to the machine body; the rotating locking piece is used for locking the rotating body at a first angle and releasing the rotating body when being triggered; the energy storage part is used for driving the rotating body to rotate towards a second angle; the travel wheel triggers the rotating lock piece to release the rotating body when the traveling wheel travels to reach a set condition; a transmitting section including: the carrier is used for loading the toy body; and the emission mechanism is triggered to perform emission action when the rotating body rotates relative to the machine body, and when the emission action is performed, the emission mechanism moves from the return position to the exit position so as to eject the toy body. The utility model discloses a walking wheel and the linkage of rotatory latch fitting increase and penetrate the toy action eye-catching soon, strengthen holistic interest, arouse the enjoyment of playing.

Description

Rotary shooting toy capable of being triggered by walking

Technical Field

The utility model belongs to the technical field of the toy technique and specifically relates to a can walk and trigger penetrate toy soon.

Background

Toys are pursued by the masses of enthusiasts through the interestingness of the toys, the current triggering toys are more popular, for example, toy vehicles realize deformation, jumping and the like through triggering, and the adopted triggering modes are various, such as magnetic attraction triggering, collision triggering and electric control triggering. These trigger modes all need to be realized with the help of other carriers, need take place magnetism with other carriers, collide or signal reception, just can realize triggering, so the operation is comparatively troublesome, to the less child of the age that the manipulative ability is relatively poor, then hardly realize the action that triggers, and the method of playing is single moreover, and the interest is relatively poor, can't arouse child's enjoyment of playing.

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 but walk triggering penetrate toy soon increases the playing method who penetrates the toy soon, improves the interest that penetrates the toy soon.

According to the utility model discloses but rotatory of walking trigger penetrates toy, include: the device comprises a machine body, wherein a travelling wheel is arranged on the machine body; a rotating portion, comprising: a rotating body rotatably coupled to the body; the rotating locking part is used for locking the rotating body at a first angle, and the rotating locking part releases the rotating body when being triggered; the energy storage part is connected between the machine body and the rotating body and is used for driving the rotating body to rotate towards a second angle; the travel trigger assembly is respectively linked with the traveling wheel and the rotary locking piece, and the traveling wheel triggers the rotary locking piece to release the rotary body through the travel trigger assembly when traveling reaches a set condition; a transmitting section, the transmitting section comprising: a carrier provided on at least one of the body and the rotating body, the carrier being for loading a toy body; the launching mechanism is triggered to execute launching action when the rotating body rotates relative to the machine body, and moves from a return position to an exit position to launch the toy body when the launching action is executed.

According to the utility model discloses but walking trigger penetrates toy soon, through the linkage of walking wheel with rotatory latch fitting, it is rotatory to trigger the rotator after the walking wheel reaches the settlement condition, and the transmission part launches the toy body in the rotator is rotatory, has realized walking-rotatory-a series of actions of penetrating soon to make this toy dynamic effect more striking, strengthen holistic interest, arouse the enjoyment of playing.

In some embodiments, the trip trigger assembly comprises: the first meshing part is connected with the travelling wheel; the second meshing part is rotatably arranged on the machine body and meshed with the first meshing part; the locking piece, the locking piece is movably established between first position and second position on the organism, the locking piece is in when first position rotatory latch fitting is locked, can loop through in the walking wheel in proper order first mesh piece, second mesh piece drives the locking piece moves to the second position, when the second position the locking piece releases rotatory latch fitting, rotatory latch fitting releases the rotator.

Further, the spinning toy further comprises: the first sliding part is arranged on the machine body between an initial position and a final position in a sliding manner, the first sliding part is constructed to move towards the final position constantly, the locking part is respectively matched with the first sliding part and the second meshing part, the locking part is used for locking the first sliding part at the initial position, and when the travelling wheel rotates to drive the second meshing part to rotate, the locking part is driven to release the first sliding part; rotatory latch fitting with first slide links to each other, first slide is in when just the position rotatory latch fitting lock solid the rotator, first slide is in when the end position rotatory latch fitting release the rotator.

Still further, the stroke trigger assembly further comprises: the second sliding piece is arranged below the first sliding piece in a sliding mode, and the locking piece is matched with the first sliding piece and the second sliding piece respectively; the second meshing piece is in linkage with the second sliding piece, and the second sliding piece moves when the second meshing piece rotates.

In some specific embodiments, be equipped with the locking piece on the locking piece, be equipped with the locked groove on the first sliding piece, when the locking piece is located the locked groove the first sliding piece is located just to be put, the bottom cooperation of locking piece is in on the second sliding piece, drive when the second sliding piece slides the locking piece reciprocates, the locking piece drives when moving up the locking piece breaks away from the locked groove.

In other specific embodiments, a cam is arranged on the second engaging member, and the cam abuts against the second sliding member.

In some embodiments, the first engaging member is a worm gear, and transition teeth are disposed between the first engaging member and the second engaging member.

Preferably, the carrier carries a plurality of said toy bodies, and said launching mechanism is configured to perform a launching action a plurality of times and to launch one of said toy bodies off said rotator each time said launching action is performed.

Furthermore, the emission mechanism has a plurality ofly, every emission mechanism all includes transmission piece and transmission elastic component, the emission part still includes locking mechanism, locking mechanism is used for with all the transmission piece lock solid is in the return, locking mechanism is every unblock one the transmission piece, the transmission elastic component drive unblock the transmission piece orientation the activity of leaving the position, at least two when being unblock the rotator is different relative the rotation angle of organism.

Furthermore, a plurality of trigger bulges are arranged on the machine body, and at least two trigger bulges are arranged at intervals in the circumferential direction of the covering surface of the rotating body rotating relative to the machine body; the locking mechanism comprises a plurality of locking pieces used for locking the plurality of the launching pieces at the returning positions respectively, and the locking pieces are pushed to unlock the launching pieces when passing through the trigger bulges.

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 overall structure of a walk-triggered spiral shooting toy according to an embodiment of the present invention;

fig. 2 is a schematic view of the internal structure of the machine body according to the embodiment of the present invention;

fig. 3 is a schematic view of a part of the structure of the stroke trigger assembly according to the embodiment of the present invention;

fig. 4 is a schematic view illustrating the engagement between the locking member and the second sliding member according to the embodiment of the present invention;

FIG. 5 is a schematic view of the transmitting portion and the deforming member according to an embodiment of the present invention;

fig. 6 is a schematic view of the rotating part and the housing according to the embodiment of the present invention;

FIG. 7 is a schematic diagram of the cooperation between the emitting portion and the trigger protrusion in the embodiment of the present invention;

fig. 8 is a schematic structural diagram of an emitting portion in an embodiment of the present invention.

Reference numerals are as follows:

100. a walk-triggerable rotary shooting toy;

10. a body; 11. a traveling wheel; 13. a fastener; 131. a fifth elastic member; 14. a trigger protrusion;

20. a deformation assembly; 21. a deformation member; 23. unfolding the locking piece; 231. a fourth elastic member;

40. a rotating portion; 41. a rotating body; 42. rotating the locking member; 43. an energy storage member;

50. a transmitting section;

58. a carrier; 51. a toy body;

52. a launching mechanism; 521. a launcher; 5211. a launch lock portion; 522. a launching spring;

53. a cover is turned; 531. a third elastic member;

54. a locking mechanism; 541. a locking member;

55. a carrier plate; 551. blocking edges; 5511. a guide hole;

56. resetting the assembly; 561. resetting the locking piece; 562. resetting the trigger;

57. a limiting mechanism; 571. a limiting member; 572. a limiting elastic part;

60. a first glide; 61. locking the groove; 62. a first elastic member; 63. a strip-shaped groove;

80. a trip trigger assembly;

81. a first engaging member;

82. a second engaging member; 821. a cam;

83. a transition tooth;

22. a locking member; 221. a locking block; 222. a second cylinder; 223. a third cylinder; 224. a second elastic member;

30. a second glide; 31. a guide surface; 32. and a sixth elastic member.

Detailed Description

Reference will now be made in detail to the 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 functions 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 "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "circumferential", 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, features defined as "first" and "second" may explicitly or implicitly include one or more of the features for distinguishing between descriptive features, non-sequential, non-trivial and non-trivial.

In the description of the present invention, "a plurality" means two or more unless otherwise specified.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected" and "connected" are to be construed broadly, 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 as a specific case by those skilled in the art.

A walk-activated spinning jet toy 100 according to an embodiment of the present invention will be described with reference to the drawings.

As shown in fig. 1, 3 and 5, a walk-triggered spinning toy 100 according to an embodiment of the present invention includes: body 10, rotating part 40, stroke trigger assembly 80, and launching part 50.

The machine body 10 is provided with a traveling wheel 11, and the machine body 10 is supported by the traveling wheel 11 and travels.

As shown in fig. 6, the rotating portion 40 includes: rotating body 41, rotating lock 42, and energy storage 43.

The rotating body 41 is rotatably coupled to the body 10.

The rotary lock 42 is used to lock the rotator 41 at a first angle, and the rotary lock 42 releases the rotator 41 when triggered. It should be noted that, because the rotating body 41 is rotatable relative to the machine body 10, by providing the rotating lock 42, in a specific example, the position of the rotating body 41 relative to the machine body 10 can be adjusted by controlling the rotating lock 42, and the releasing is referred to herein as that the rotating body 41 can rotate relative to the machine body 10 when the rotating lock 42 is triggered, that is, when the rotating lock 42 locks the rotating body 41, the rotating body 41 is fixed relative to the machine body 10, and when the rotating lock 42 unlocks the rotating body 41, the rotating body 41 rotates relative to the machine body 10.

The energy storage member 43 is connected between the body 10 and the rotating body 41 for driving the rotating body 41 to rotate toward the second angle. That is, the energy storage member 43 is used for driving the rotation member 41 to rotate between a first angle and a second angle relative to the machine body 10.

In some specific examples, the energy storage component 43 can be a return force gearbox, the return force gearbox is connected to one of the machine body 10 and the rotating body 41, the rotating body 41 is driven to rotate by using the return force gearbox, other driving components are omitted, the space utilization rate of the spinning toy 100 is improved, when the rotating body 41 rotates from the first angle to the second angle, the return force gearbox is in an energy release state, when the rotating body 41 is manually driven to rotate from the second angle to the first angle, the energy storage process of the return force gearbox is substantially given, it is ensured that when the rotating body 41 is at the first angle, the return force gearbox is always in an energy storage state, and after the rotating lock component 42 releases the rotating body 41, the rotating body 41 can rotate towards the second angle.

It should be noted that, here, the process of manually driving the rotating body 41 to rotate to store energy in the return gear box improves the interest of the rotary shooting toy 100 and improves the manipulability of the child.

The travel trigger assembly 80 is respectively linked with the traveling wheel 11 and the rotating lock 42, and the traveling wheel 11 triggers the rotating lock 42 to release the rotating body 41 through the travel trigger assembly 80 when the traveling reaches a set condition. It should be noted that the setting conditions may be preset, for example, the walking wheels 11 are preset to rotate for one turn, or the walking wheels 11 walk for a certain distance, etc., and releasing the rotating body 41 after the walking wheels 11 reach the setting conditions brings curiosity to people, and increases the fun brought by the spin-shooting toy 100.

As shown in fig. 1 and 5, the transmitting section 50 includes: carrier 58, launching mechanism 52.

A carrier 58 is provided on at least one of the body 10 and the rotating body 41, the carrier 58 being for loading the toy body 51. For example, the carrier 58 is provided on the body 10; alternatively, the carrier 58 is provided on the rotating body 41; alternatively, the body 10 and the rotating body 41 are both provided with the carrier 58 for loading the toy body 51, and for convenience of description, the carrier 58 is provided on the rotating body 41. It should be noted that the toy body 51 may be a toy coin or a toy car.

When the rotating body 41 rotates relative to the machine body 10, the launching mechanism 52 is triggered to execute a launching action, and when the launching action is executed, the launching mechanism 52 moves from a return position to an exit position to shoot the toy body 51 away. It is understood that the launching mechanism 52 triggered by the rotation of the rotating body 41 relative to the body 10 does not necessarily perform the launching action immediately, and the launching from the toy body 51 may be performed after a certain time after the rotation of the rotating body 41 occurs; alternatively, the shooting away of the toy body 51 may be performed at the first time when the rotation of the rotator 41 occurs; alternatively, the shooting away of the toy body 51 may be performed during the rotation of the rotating body 41, so that the spinning toy 100 exhibits a spinning effect of shooting the toy body 51 while rotating.

Such a spinning toy 100 may create multiple play scenarios with smart controls during play, such as:

1. the rotary shooting toy 100 is placed on the ground (or other supporting surfaces such as a table top and a box surface), the rotary locking piece 42 locks the rotary body 41 at a first angle, after the walking wheel 11 walks to reach a set condition, the rotary locking piece 42 releases the rotary body 41, the energy storage piece 43 drives the rotary body 41 to rotate relative to the machine body 10, the rotary body 41 drives the carrier 58 to rotate together in the rotating process, and the rotary body 41 triggers the launching mechanism 52 to execute a launching action in the rotating process, so that the launching mechanism 52 moves towards an outgoing position and launches the toy body 51, the rotary shooting toy 100 rotates while launching the toy body 51, and a new playing method and a visual effect launched by the rotary shooting toy 100 are increased.

2. The rotary shooting toy 100 is placed on the ground (or other supporting surfaces such as a table top and a box surface) or held in a hand, one hand fixes the machine body 10, the other hand rotates the rotating body 41, the rotating body 41 rotates to the first angle from the second angle, manual resetting of the rotary shooting toy 100 is achieved, energy is stored in the energy storage part 43 in the resetting process, and the rotary shooting toy is labor-saving, rapid and high in interestingness.

Optionally, when launching mechanism 52 is moved toward the out position, the spinning toy 100 is triggered to at least one of empty, deform, shoot, sound, and glow. The rotary shooting toy 100 is more diversified after being rotated, the interestingness of the rotary shooting toy 100 is further improved, and the attention of children is attracted.

According to the utility model discloses what can walk and trigger penetrates toy 100 soon, through walking wheel 11 and rotatory latch fitting 42's linkage, it is rotatory to trigger rotator 41 after walking wheel 11 reaches the settlement condition, and transmitting part 50 launches toy body 51 in the rotatory while of rotator 41 to increase and penetrate toy 100 action eye-catching soon, strengthen holistic interest, arouse the enjoyment of playing.

In some embodiments, as shown in fig. 1, 3 and 4, the trip trigger assembly 80 includes: a first engaging member 81, a second engaging member 82, and a locking member 22. The first engaging member 81 is connected with the traveling wheels 11, and the first engaging member 81 is driven by the traveling wheels 11 to move.

The second engaging member 82 is rotatably disposed on the body 10, the second engaging member 82 is engaged with the first engaging member 81, and the movement of the first engaging member 81 drives the second engaging member 82 to rotate.

The locking piece 22 is movably arranged on the machine body 10 between a first position and a second position, the rotating locking piece 42 is locked when the locking piece 22 is in the first position, the walking wheel 11 can drive the locking piece 22 to move to the second position through the first meshing piece 81 and the second meshing piece 82 in sequence in the rotation process, the rotating locking piece 42 is released by the locking piece 22 when the walking wheel is in the second position, and the rotating locking piece 42 releases the rotating body 41. Through the stroke trigger assembly 80, the first meshing part 81, the second meshing part 82 and the locking part 22 are arranged, when the walking of the walking wheel 11 reaches a set condition, the first meshing part 81 drives the second meshing part 82 to rotate by a set angle, so that the locking part 22 releases the rotary locking part 42, the automatic unlocking of a preset stroke can be realized, and the interestingness is stronger.

As shown in fig. 2, further, the spinning toy 100 further includes: the first sliding member 60 is slidably arranged on the machine body 10 between an initial position and a final position, the first sliding member 60 is configured to move towards the final position, the locking member 22 is respectively matched with the first sliding member 60 and the second meshing member 82, the locking member 22 is used for locking the first sliding member 60 at the initial position, and when the travelling wheel 11 rotates to drive the second meshing member 82 to rotate, the locking member 22 is driven to release the first sliding member 60; the rotating locking member 42 is connected to the first sliding member 60, the rotating locking member 42 locks the rotating body 41 when the first sliding member 60 is in the initial position, and the rotating locking member 42 releases the rotating body 41 when the first sliding member 60 is in the final position. For example, when the rotating toy 100 is in an initial state, the first sliding member 60 is in an initial position, the locking member 22 is locked on the first sliding member 60, the locking member 22 is movable to release the first sliding member 60 when the traveling wheel 11 travels to a set condition, the first sliding member 60 moves forward, that is, the first sliding member 60 moves to a final position, and when the first sliding member 60 moves to the final position, because the rotating lock member 42 is connected with the first sliding member 60, the rotating lock member 42 moves forward along with the first sliding member 60, the rotating body 41 is unlocked by the rotating lock member 42, and the rotating body 41 is thereby rotated.

Specifically, as shown in fig. 2, a first elastic member 62 is disposed between the first sliding member 60 and the machine body 10, and the first sliding member 60 is moved towards the end position by the elastic action of the first elastic member 62, so that the machine is simple and durable. For example, the first elastic member 62 is a spring, one end of the spring abuts against the rear side of the first sliding member 60, the other end of the spring abuts against the inner wall of the machine body 10, and when the first sliding member 60 is in the initial position, the spring is in a compressed state and applies a forward force to the first sliding member 60.

More specifically, the second engaging member 82 may further include an extending portion (not shown) connected to the locking member 22, wherein the locking member 22 moves to the second position during movement of the extending portion. In particular, the extension has an inclined surface which abuts on the locking element 22, during the movement of the extension, the locking element 22 being pushed by the inclined surface to move to the second position. For example, the extension is below the locking element 22, the slope is inclined upwards, during the rotation of the extension, the locking element 22 slides on the slope and the locking element 22 moves upwards.

Further, as shown in fig. 2, the stroke trigger assembly 80 further includes: the second sliding part 30, the second sliding part 30 is set under the first sliding part 60 slidably, the locking piece 22 cooperates with first sliding part 60, second sliding part 30 separately; the second engaging member 82 is coupled to the second slide 30, and the second slide 30 moves when the second engaging member 82 rotates. Specifically, the second engaging member 82 rotates to drive the second sliding member 30 to move, the second sliding member 30 triggers the locking member 22 to move from the first position to the second position, the locking member 22 triggers the first sliding member 60 to unlock in the process of moving towards the second position, the first sliding member slides from the initial position to the final position, the rotating locking member 42 connected with the first sliding member 60 releases the rotating body 41, and the rotating body 41 rotates.

In some embodiments, as shown in fig. 2, a locking piece 221 is disposed on the locking piece 22, a locking groove 61 is disposed on the first sliding member 60, when the locking piece 221 is located in the locking groove 61, the first sliding member 60 is located at an initial position, the bottom of the locking piece 22 is engaged with the second sliding member 30, when the second sliding member 30 slides, the locking piece 22 is driven to move up and down, and when the locking piece 22 moves up, the locking piece 221 is driven to disengage from the locking groove 61. It can be understood that the first sliding member 60 is configured to move towards the end position, when the locking piece 221 is located in the locking slot 61, the first sliding member 60 is blocked from moving, the second sliding member 30 drives the locking member 22 to move upwards, the locking piece 221 is separated from the locking slot 61, and the first sliding member 60 loses the blocking and moves towards the end position.

Specifically, the locking piece 221 is located between the motion tracks of the first sliding member 60, and the first sliding member 60 cannot move under the obstruction of the locking piece 221. For example, the first sliding member 60 can move in the front-rear direction, the locking groove 61 is a vertical through hole on the first sliding member 60, when the locking block 221 is located in the locking groove 61 when the first sliding member 60 is located in the initial position, the first sliding member 60 cannot move in the front-rear direction, the second sliding member 30 moves backward to drive the locking block 221 to move upward to be separated from the locking groove 61, the first sliding member 60 loses the obstruction of the locking block 221, and the first sliding member 60 is configured to move toward the last position of the first sliding member 60 which always moves toward the last position, that is, the first sliding member 60 moves forward; or, the first sliding member 60 can move in the up-down direction, the locking groove 61 is a horizontal through hole on the first sliding member 60, when the locking block 221 is located in the locking groove 61 when the first sliding member 60 is located at the initial position, the first sliding member 60 cannot move in the up-down direction, the second sliding member 30 drives the locking block 221 to move leftward to separate from the locking groove 61, the blocking of the locking block 221 is lost, and the first sliding member 60 which normally moves toward the last position, that is, the first sliding member 60 moves upward; of course, the first sliding member 60 can also move in any other direction, and the description is omitted here.

In some embodiments, as shown in fig. 2 and 4, the locking piece 221 is a first cylinder, and the locking member 22 further includes a second cylinder 222, the second cylinder 222 is connected to a side of the first cylinder adjacent to the second sliding member 30; the locking groove 61 is a circular groove formed on the first sliding member 60, and a strip-shaped groove 63 connected with the circular groove is further formed on the first sliding member 60; when the first cylinder is located in the circular groove, the first sliding part 60 is located at the initial position, the second sliding part 30 triggers the second cylinder 222 to move into the circular groove, and when the first sliding part 60 slides towards the final position, the second cylinder 222 is located in the strip-shaped groove 63, so that the interference of the movement of the first sliding part 60 can be avoided.

Specifically, the second cylinder 222 and the first cylinder are coaxial, the second cylinder 222 is located below the first cylinder, the diameter of the second cylinder 222 is smaller than that of the first cylinder, the aperture of the circular groove is matched with that of the first cylinder, the width of the strip-shaped groove 63 is smaller than that of the first cylinder, and the width of the strip-shaped groove 63 is larger than that of the second cylinder 222; when the first cylinder is located in the circular groove, the first slider 60 cannot move; the second sliding member 30 pushes the first cylinder and the second cylinder 222 to move upwards, the second cylinder 222 moves into the circular groove, because the width of the strip-shaped groove 63 is greater than the diameter of the second cylinder 222, the second cylinder 222 can enter the strip-shaped groove 63, and the first sliding member 60 is unlocked to slide towards the end to drive the rotary locking member 42 to unlock the rotating body 41.

In other embodiments, as shown in fig. 4, the second sliding member 30 is provided with a guide surface 31 contacting the bottom of the locking member 22, and the guide surface 31 is formed to gradually extend upward to lift the locking member 22 when the second sliding member 30 moves. For example, the bottom of the locking member 22 is configured to be a hemisphere, and the guiding surface 31 on the second sliding member 30 is slidably connected to the hemisphere, because the guiding surface 31 is an inclined surface and gradually extends upward, when the second sliding member 30 moves backward, the hemisphere slides on the guiding surface 31, so that the locking member 22 can be lifted up, and the first sliding member 60 can be unlocked.

More specifically, as shown in fig. 4, the locking member 22 further includes a third cylinder 223, the third cylinder 223 is connected to a side of the first cylinder far from the second sliding member 30, and the third cylinder 223 is provided with a second elastic member 224. For example, the second elastic member 224 is a spring sleeved on the third cylinder 223, the diameter of the third cylinder 223 is smaller than that of the first cylinder, the third cylinder 223 is sleeved in the first cylinder, the spring is arranged between the first cylinder and the third cylinder 223, one end of the spring abuts against the machine body 10, the other end of the spring is sleeved on the third cylinder 223, the spring keeps the elastic force of the locking member 22 to enable the locking member 22 to have a downward moving trend, and the locking member 22 is convenient to reset and lock the first sliding member 60 again.

In other embodiments, as shown in fig. 3, a cam 821 is provided on the second engaging member 82, and the cam 821 is stopped against the second sliding member 30. It will be appreciated that rotation of the second engagement member 82 causes the cam 821 to follow the rotation, and rotation of the cam 821 against the second slide 30 moves the second slide 30. For example, the cam 821 is disposed below the second engaging member 82 and rotates coaxially with the second engaging member 82, the second engaging member 82 rotates to drive one end of the cam 821, which is stopped against the second sliding member 30, to move backward, and the second sliding member 30 is pushed by the cam to move backward.

Preferably, as shown in fig. 2 and 3, a sixth elastic element 32 is disposed between the second sliding element 30 and the machine body 10, one end of the sixth elastic element 32 abuts or is connected to the machine body 10, the other end abuts or is connected to the second sliding element 30, and the sixth elastic element 32 provides a force to abut the second sliding element 30 on the cam 821. Specifically, the sixth elastic element 32 is a spring, a front end of the spring abuts against the second sliding element 30, a rear end of the spring abuts against the machine body 10, the spring is in a compressed state, and the elastic force of the spring makes the second sliding element 30 have a tendency of moving forward, so that the second sliding element 30 always abuts against the cam 821, and the second sliding element 30 is moved and reset.

In some embodiments, the first engagement member 81 is a worm gear, and a transition tooth 83 is disposed between the first engagement member 81 and the second engagement member 82. Specifically, the transition tooth 83 is a worm, the worm gear and the worm mesh to change the rotation direction, and the worm meshes with the second meshing part 82 to transmit rotation.

In other embodiments, as shown in fig. 3, the first engagement member 81 is a worm, and a transition tooth 83 is provided between the first engagement member 81 and the second engagement member 82. Specifically, the worm may be disposed on a wheel shaft of the walking wheel 11, the transition tooth 83 is a worm wheel, the walking wheel 11 drives the worm to rotate in a rotation process, and further drives the worm wheel connected to the worm, and the second engaging member 82 rotates on the machine body 10, because the transmission ratio of the worm and the worm wheel is small, the worm wheel can rotate by a preset angle only when the worm rotates for a long number of turns, so as to unlock and release the first sliding member 60, thereby greatly increasing a stroke of the rotational shooting toy 100 and increasing playability.

Preferably, as shown in fig. 1 and 5, the carrier 58 carries a plurality of toy bodies 51, and the launching mechanism 52 is configured to execute a launching action a plurality of times and to eject one of the toy bodies 51 away from the rotator 41 each time the launching action is executed. It should be noted that, one rotation of the transmitting structure 52 from the first angle to the second angle of the rotating body 41 may be to perform one transmitting action, and one rotation of the transmitting structure from the first angle to the second angle of the rotating body 41 may also be to perform multiple transmitting actions. For example, the carrier 58 is loaded with 4 toy bodies 51, the launching mechanism 52 executes a launching action along with one rotation of the rotating body 41 from the first angle to the second angle, 1 toy body 51 is launched from the carrier 58, 3 toy bodies 51 are left on the carrier 58, the rotating body 41 is rotated to the first angle, the rotating body 41 is rotated to the second angle from the first angle to be launched from the 1 toy body 51 again, and the cycle is repeated until all 4 toy bodies 51 are launched from the carrier 58; or, the launching mechanism 52 executes a plurality of launching actions in one rotation process from the first angle to the second angle along with the rotating body 41, 4 toy bodies 51 are mounted on the carrier 58, and the launching mechanism 52 executes 4 launching actions successively, so that a continuous spinning effect is realized, the visual experience is improved, and the interestingness of the spinning toy 100 is improved.

Further, as shown in fig. 5 and 7, the plurality of launching mechanisms 52 are provided, each launching mechanism 52 comprises a launching element 521 and a launching elastic element 522, the launching part 50 further comprises a locking mechanism 54, the locking mechanism 54 is used for locking all the launching elements 521 in the return position, each launching element 521 is unlocked by the locking mechanism 54, the launching elastic element 522 drives the unlocked launching element 521 to move towards the exit position, the rotation angles of the rotating body 41 relative to the machine body 10 are different when at least two launching elements 521 are unlocked, the rotation angles of the rotating body 41 relative to the machine body 10 are different when at least two launching elements 521 are shot away, so that the plurality of toy bodies 51 can be launched towards a plurality of angles in sequence, and the interest of the rotary shooting toy 100 is improved. For example, the number of the toy bodies 51 is 4, the number of the emission mechanisms 52 is 4 corresponding to the number of the toy bodies 51, the emission piece 521 is locked by the locking mechanism 54 to return, after the emission piece 521 is unlocked by the locking mechanism 54, the emission piece 521 moves backwards, namely, the emission piece 521 moves towards the outward position, the emission piece 521 collides against the toy bodies 51 in the process that the emission piece 521 moves backwards, and the impact force ejects the toy bodies 51 to finish the emission action. When the 4 launching elements 521 are unlocked, the rotation angles of the rotating body 41 relative to the machine body 10 are all different, so that a continuous rotating shooting effect is formed; of course, the rotation angle of the rotating body 41 relative to the machine body 10 when the 2 emitting elements 521 of the 4 emitting elements 521 and the other 2 emitting elements 521 are unlocked may be different, and other various combinations have the same effect, and are not described herein again.

In some specific examples, the launching elastic member 522 may be a spring, and the spring has a certain expansion and contraction force to drive the launching member 521 to move toward the exit position.

Further, as shown in fig. 7, a plurality of trigger protrusions 14 are provided on the machine body 10, and at least two trigger protrusions 14 are provided at intervals in a circumferential direction of a cover surface of the rotating body 41 rotating relative to the machine body 10; the locking mechanism 54 includes a plurality of locking members 541 for locking the plurality of emitters 521 in the returned positions, respectively, and the locking members 541 are pushed to unlock the emitters 521 when passing the trigger protrusion 14. Specifically, there are 4 toy bodies 51, there are 4 launching members 521 provided corresponding to the toy bodies 51, 4 locking members 541 are correspondingly locked on the 4 launching members 521 to lock the launching members 521 in the return position, there are 4 trigger protrusions 14 provided on the upper surface of the body 10, the 4 trigger protrusions 14 correspond to the 4 locking members 541 one by one, when the rotating body 41 rotates, the locking members 541 come into contact with the corresponding trigger protrusions 14, the locking members 541 are jacked up by the trigger protrusions 14 to move up to unlock the launching members 521, the launching members 521 move towards the exit position under the driving of the launching elastic members 522 to launch the toy bodies 51; the shooting time of the toy bodies 51 can be controlled by setting the positions of the 4 trigger bulges 14, the shooting conditions of the 4 toy bodies 51 at different times can be constructed, and the effect of continuous rotating shooting is formed.

It should be noted that, because a certain time is required for the rotator 41 to reach from one position to the other position in the rotating process, the interval arrangement of the at least two trigger protrusions 14 can ensure that the time points of the at least two toy bodies 51 being launched are different in the launching process of the toy bodies 51; on the other hand, it can be ensured that the positions where at least two toy bodies 51 are launched are different in the process of launching the toy bodies 51, so that the plurality of toy bodies 51 can be launched towards a plurality of angles in a successive manner in the process of rotating the rotating body 41, and the interestingness of the spinning toy 100 is improved.

Optionally, the launching part 50 further comprises a driving mechanism (not shown), the driving mechanism is connected with the launching mechanism 52, and the driving mechanism can drive the launching mechanism 52 to intermittently execute launching action after the locking mechanism 54 is unlocked by the triggering protrusion 14, so that the plurality of toy bodies 51 can be sequentially launched.

In a specific example, the driving mechanism includes a motor, a transmission gear, a clutch gear and a half-tooth gear, wherein the clutch gear and the half-tooth gear are coaxially and synchronously linked, when the locking mechanism 54 is unlocked, the clutch gear is engaged with the transmission gear to drive the half-tooth gear to rotate, the half-tooth gear can drive a rack arranged on the launching mechanism 52 to move backwards, so that launching energy storage is realized, when teeth of the half-tooth leave the rack, launching energy release is realized, and then the half-tooth rotates to be engaged with the rack again, energy storage is carried out again, and the steps are repeated.

That is, it is not limited that only the trigger protrusion 14 unlocks the transmitter 521, and other structures may be used to unlock the transmitter 521. Such as an eccentric cam that triggers the unlocking of the launcher 521 once per revolution of the eccentric cam.

Alternatively, as shown in fig. 8, a plurality of the transmitting members 521 are stacked, a stacking direction of the plurality of the transmitting members 521 is perpendicular to a transmitting direction of the transmitting members 521, at least one side of each of the transmitting members 521 is provided with a transmitting lock portion 5211, and each of the locking members 541 is adapted to be caught on the transmitting lock portion 5211 of the corresponding transmitting member 521. Through setting up transmission lock portion 5211, make things convenient for locking piece 541 joint on the transmitter 521 to lock the transmitter 521 in return position, ensure that the transmitter 521 can not launch the toy body 51 when the locking piece 541 is not moving towards the direction of breaking away from the transmitter 521.

Alternatively, as shown in fig. 7, only one launching lock portion 5211 is provided per launching member 521. Because the launching lock portions 5211 are clamped with the lock pieces 541, if a plurality of launching lock portions 5211 are arranged on each launching piece 521, the number of the lock pieces 541 is correspondingly increased, and on one hand, the launching difficulty of the spinning toy 100 is increased; on the other hand, the structure of the spinning toy 100 is complicated, which increases the difficulty of manufacturing.

Alternatively, as shown in fig. 7, the launching lock portions 5211 of two adjacent layers are located on opposite sides of the launching mechanism 52, and the launching lock portions 5211 on the same side are spaced apart in the launching direction. The launching lock portions 5211 arranged at intervals provide convenience for arrangement of the locking pieces 541, sufficient space is ensured to be provided for the locking pieces 541, and it is also ensured that the adjacent two locking pieces 541 cannot interfere in the moving process of the locking pieces 541, so that the toy body 51 can be launched smoothly in the launching process.

Optionally, as shown in fig. 7, the transmitting part 50 further includes: at least two bearing plates 55 are stacked, each bearing plate 55 is provided with a movable emitting piece 521, and the bearing plates 55 are provided with flanges 551 which stop at two opposite sides of the emitting piece 521. The rib 551 is used for limiting the position of the emitting element 521, when the emitting elastic element 522 drives the emitting element 521 to move towards the outward position, the emitting element 521 will move along the extending direction of the rib 551, so as to ensure that the emitting element 521 does not deviate in the moving process, so that the emitting element 521 can accurately emit the toy body 51.

Alternatively, as shown in fig. 7, the stacking direction of the carrier plate 55 is the same as the stacking direction of the radiator 521. So that the carrier plate 55 can carry a movable radiator 521 therein, and the radiator 521 can radiate along the extending direction of the carrier plate 55.

Alternatively, as shown in fig. 7, a guide hole 5511 is formed on the rib 551, and a part of the radiator 521 passes through the guide hole 5511 to engage with the locking member 541. The guide hole 5511 is used to provide an escape space to ensure that a portion of the radiator 521 can smoothly pass through the carrier plate 55 to engage with the lock 541.

As shown in fig. 7, in some specific examples, a guide hole 5511 is formed on the rib 551, and the launching lock portion 5211 protrudes through the guide hole 5511 to engage with the lock member 541. The guide hole 5511 is used to provide a space for escape, ensuring that the launching lock portion 5211 can smoothly engage with the lock member 541 through the carrier plate 55.

Optionally, as shown in FIG. 8, a firing spring 522 is connected between the carrier plate 55 and the firing member 521. When the launching member 521 is in the return position, the carrier plate 55 and the launching member 521 cooperate to press the launching elastic member 522, and at this time, the launching elastic member 522 is compressed under the action of the pressing force and generates further pushing force to the launching member 521, so that the launching elastic member 522 can drive the launching member 521 to move towards the exit position by using the elastic restoring force of the launching elastic member 522 when the locking mechanism 54 unlocks the launching member 521.

Alternatively, as shown in fig. 1 and 2, the traveling wheels 11 are provided in plurality. For example, the bottom of the body 10 is provided with four road wheels 11, the four road wheels 11 are rectangular, the whirl-shoot toy 100 is supported on a plane through the road wheels 11, meanwhile, the whirl-shoot toy 100 walks on the plane through the rolling road wheels 11, the whirl-shoot toy 100 can be controlled to rotate and shoot the toy body 51 through planning of a traveling path, the planning capability of a player is improved, and meanwhile, the action process of the whirl-shoot toy 100 is strongly attractive.

Optionally, as shown in fig. 7, the launching part 50 further includes a limiting mechanism 57, the limiting mechanism 57 is provided on the rotating body 41, and the limiting mechanism 57 is used for providing resistance when the toy body 51 is launched. The launching distance of the toy body 51 can be shortened by applying resistance to the toy body 51 through the limiting mechanism 57, on one hand, after the toy body 51 is launched, a child can easily retrieve the toy body 51, and the toy body 51 cannot be lost; on the other hand, when a plurality of children play the spin-shooting toy 100 at the same time, the toy body 51 with a close shooting range cannot be shot to the children in the shooting process, namely, the children cannot be injured, and the safety of the spin-shooting toy 100 is improved.

It should be noted that the resistance of the limiting mechanism 57 acting on the toy body 51 is smaller than the elastic restoring force of the launching elastic member 522, so that when the launching elastic member 522 drives the launching member 521 to move towards the exit position, the toy body 51 can be launched towards the outside of the rotating body 41 by overcoming the resistance.

Of course, in other examples, the limiting mechanism 57 not only provides resistance to the toy body 51 but also can be used to limit the position of the toy body 51, when the launcher 521 does not launch the toy body 51 towards the out-position event, the limiting mechanism 57 can ensure that the position of the toy body 51 in the carrier 58 is stable, ensure that the launcher 521 can launch the toy body 51 accurately when the launcher 521 is towards the out-position event, and improve the accuracy of the spinning-shooting toy 100 in launching the toy body 51.

Alternatively, as shown in fig. 7, the limiting mechanism 57 includes: the position-limiting members 571 are telescopically disposed at one end of the rotating body 41, and the two opposite sides of the rotating body 41 are each provided with a position-limiting member 571. The telescopically arranged limiting member 571 ensures that when the launching member 521 is located at the return position, the limiting member 571 extends and retracts towards the direction close to the toy body 51, and the limiting member 571 is used for limiting the position of the toy body 51, so that the toy body 51 can be stably arranged in the carrier 58; when the launching element 521 is located at the exit position, the toy body 51 applies a force to the position-limiting element 571, the position-limiting element 571 extends and retracts in the direction away from the toy body 51, and the toy body 51 can be launched from one end of the carrier 58 smoothly.

Optionally, as shown in fig. 7, the limiting mechanism 57 further includes a plurality of limiting elastic members 572, one limiting elastic member 572 is disposed on one side of each limiting member 571, and the limiting elastic members 572 are configured to drive the limiting members 571 to move towards the toy body 51.

Optionally, the limiting elastic member 572 can be a spring, which has a certain elastic force to drive the limiting member 571 to move, and the spring has a low cost and is easy to control.

As shown in fig. 8, the launching section 50 optionally further comprises a reset assembly 56.

Wherein, the reset assembly 56 includes a reset lock 561 and a reset trigger 562 (the specific structure of the reset lock 561 and the reset trigger 562 can refer to fig. 8), the reset lock 561 is connected to the first emitting element 521 that emits, and the reset lock 561 is disposed on the other emitting elements 521 in a penetrating manner, and when the first emitting element 521 that emits moves to the return position, the reset lock 561 drives the other emitting elements 521 to move to the return position. Through the arrangement, in the resetting process, one resetting lock 561 can drive the plurality of launching elements 521 to reset, so that the number of the resetting locks 561 is saved, and the rotary shooting toy 100 is simple in structure and convenient to control; on the other hand, the reset efficiency can be improved.

Further, the reset assembly 56 may also have a locking function in addition to the reset function, and after the reset assembly 56 drives all the transmitting members 521 to move to the return position, the reset assembly 56 also stops at the corresponding position, i.e. all the transmitting members 521 are locked to the return position.

Alternatively, the reset trigger 562 locks the reset lock 561 when the rotary lock 42 locks the rotary body 41 at the first angle, and drives the reset trigger 562 to release the reset lock 561 when the rotary lock 42 releases the rotary body 41, so that the reset lock 561 releases all the radiators 521. The reset trigger 562 is used to define the position of the reset lock 561, so as to achieve double locking of the reset lock 561 and the lock 541 to the radiators 521, ensure that the locking mechanism 54 can lock all the radiators 521 in the return position when the rotary lock 42 does not release the rotary body 41, and when the rotary lock 42 releases the rotary body 41, the reset trigger 562 releases the reset lock 561 to facilitate the movement of the subsequent radiators 521 toward the exit position.

In a specific example, as shown in fig. 8, the reset lock 561 is connected to the transmitter 521 farthest from the body 10 (i.e., the first transmitter 521), and the reset lock 561 is inserted into the other transmitters 521. Through connecting the latch 561 that resets on the transmitter 521 that is apart from organism 10 farthest away, can realize that one latch 561 that resets locks a plurality of transmitters 521, when the farthest transmitter 521 is located the return, other transmitters 521 all can't move towards the play position, further realize unblock transmitter 521 in proper order for the toy body 51 can be launched towards a plurality of angles.

It should be noted that, by providing the resetting locking piece 561 and the resetting triggering piece 562, when the launching toy body 51 of the spin-shooting toy 100 needs to be reset, the resetting triggering piece 562 rotates and can drive the resetting locking piece 561 to move, and because the resetting locking piece 561 is connected to the launching piece 521 farthest from the toy body 10, the resetting locking piece 561 can simultaneously drive the plurality of launching pieces 521 to move towards the return position in the moving process, so that the speed of returning the plurality of launching pieces 521 is increased.

In some embodiments, as shown in fig. 1 and 5, the spinning toy 100 further includes: the deformation assembly 20 comprises a deformation piece 21, the deformation piece 21 is movable relative to the machine body 10, the deformation piece 21 is locked by a locking piece 22, the locking piece 22 releases the deformation piece 21 when triggered, the deformation piece 21 is unfolded when released, at least part of the deformation piece 21 is exposed on the surface of the rotating shooting toy 100 when unfolded, and the shape of the rotating shooting toy 100 is increased through the unfolding of the deformation piece 21. For example, the original shape of the deformable member 21 is a vehicle, and the shape of the deformable member 21 after being unfolded is a human-like shape, so that the shape of the spinning toy 100 is enriched, attractive and fun. Of course, the original shape and the deformed shape of the deforming member 21 may be other shapes, such as a human shape, a firearm shape, an animal shape, and the like, which will not be described herein.

In some embodiments, as shown in fig. 8, deformation assembly 20 further comprises: the unfolding locking piece 23 is arranged between the locking piece 22 and the deformation piece 21, and the unfolding locking piece 23 is used for locking the deformation piece 21.

Optionally, the unlocking piece 23 is configured to be always moved toward the direction of locking the deformation piece 21 to lock the deformation piece 21.

Further, as shown in fig. 8, a fourth elastic member 231 is provided between the unfolding lock 23 and the rotating body 41. For example, the fourth elastic member 231 is a spring, one end of the spring is abutted against the rotating body 41, the other end of the spring is abutted against the upper end of the unfolding lock 23, the unfolding lock 23 can move up and down, and the unfolding lock 23 has a downward movement tendency under the action of the spring.

In some embodiments, as shown in fig. 5, the transmitting part 50 further comprises a flip 53 rotatably connected to the rotating body 41, the flip 53 being adapted to cover the toy body 51; the body 10 is further provided with a latch 13 linked with the rotary latch 42, when the rotary latch 42 releases the rotary body 41, the latch 13 releases the flip 53, and the flip 53 opens and releases the toy body 51. Specifically, the lid 53 is configured to be always rotated toward the open state, the lid 53 cannot be rotated when the locking piece 13 locks the lid 53, and once the locking piece 13 releases the lid 53, the lid 53 is rotated to be opened without being obstructed by the locking piece 13. For example, the rear end of the machine body 10 is provided with a through hole, the locking member 13 is arranged in the through hole to move back and forth, when the locking member 13 is located inside the machine body 10, the flip cover 53 is in a separated state from the locking member 13, the locking member 13 moves back to expose a part of the locking member 13 out of the machine body 10, the part of the locking member 13 exposed out of the machine body 10 can be buckled on the flip cover 53 to prevent the flip cover 53 from rotating, and once the locking member 13 moves forward to the inside of the machine body 10, the locking member 13 is lost to prevent the flip cover 53 from automatically rotating and opening and releasing the toy body 51.

Further, as shown in fig. 5, the third elastic member 531 is disposed on the flip 53, and the third elastic member 531 makes the flip 53 move towards the open state, thereby simplifying the structure. Specifically, the third elastic member 531 is a torsion spring, one end of the torsion spring is connected to the rotating body 41, and the other end of the torsion spring abuts against the flip 53.

Further, when the first slider 60 is in the initial position, the locking member 13 is configured to move toward the outside of the machine body 10. Specifically, as shown in fig. 2, a fifth elastic element 131 is disposed between the locking element 13 and the machine body 10, one end of the fifth elastic element 131 is connected to the machine body 10, and the other end of the fifth elastic element 131 abuts against the locking element 13, and the fifth elastic element 131 makes the locking element 13 always move to the outside of the machine body 10. For example, the fifth elastic element 131 is a spring, and when the first sliding element 60 is in the initial position, the fifth elastic element 131 is in a compressed state, and can apply pressure to the locking element 13, so that the locking element 13 keeps locking the flip 53; when the first sliding member 60 is at the end position, the fifth elastic member 131 is in the extended state, the fifth elastic member 131 pulls the locking member 13 to move towards the inside of the machine body 10, the locking member 13 releases the flip cover 53, and the locking member 13 releases the flip cover 53. Meanwhile, it can be understood that the fifth elastic member 131 makes the locking member 13 have a certain moving space during the process of rotating and locking the flip 53, and the fifth elastic member 131 facilitates the locking of the flip 53.

The play of one embodiment of the walk-activated projectile toy 100 of the present invention is described below with reference to fig. 1-8:

1. before the rotary shooting toy 100 walks, the rotary shooting toy 100 is placed on the ground (or other supporting surfaces such as a table top and a box surface), and the rotary shooting toy 100 is formed into an automobile shape, so that the ornamental value is extremely high.

2. The rotation shooting toy 100 starts to move, the walking wheels 11 roll on the ground to drive the first meshing part 81 to rotate, the first meshing part 81 drives the transition teeth 83 and the second meshing part 82 to rotate, and the cam 821 arranged on the second meshing part 82 rotates simultaneously.

3. The cam 821 abuts on the second sliding member 30, and the cam 821 is rotated to push the second sliding member 30 to move backwards.

4. The second sliding member 30 moves backwards to lift the locking member 22, the locking member 22 drives the unfolding locking member 23 to move upwards, the unfolding locking member 23 unlocks the deformation member 21, and the rotating shooting toy 100 is converted from the car shape into the animal shape.

5. When the walking wheel 11 reaches the set condition, the locking piece 22 moves upwards to be separated from the locking groove 61, the first sliding piece 60 which is out of obstruction moves forwards, the rotating locking piece 42 on the first sliding piece 60 also moves forwards to unlock the rotating body 41, meanwhile, the locking piece 13 which is out of pressure moves towards the inside of the machine body 10, the flip cover 53 is unlocked to rotate relative to the rotating body 41 so as to be separated from the machine body 10, at the moment, the upper half part of the spinning toy 100 is connected with one rotating shaft of the lower half part of the spinning toy 100 only with the energy storage piece 43, and because the energy storage piece 43 is already in an energy storage state at the moment, the energy storage piece 43 can drive the deformation component 20, the rotating part 40 and the launching part 50 to rotate relative to the machine body 10, so that the effect of rotating the spinning toy 100 is presented.

6. Because the first sliding member 60 moves forward, the reset trigger 562 releases the reset lock 561, the launching member 521 is unlocked in a first step, in the rotating process of the rotating body 41, because at least two trigger protrusions 14 are arranged at intervals in the circumferential direction of the covering surface of the rotating body 41 rotating relative to the machine body 10, in the rotating process of the rotating body 41 relative to the machine body 10, the bottoms of the plurality of locking members 541 abut against the tops of the plurality of trigger protrusions 14 in sequence, the trigger protrusions 14 are used for driving the locking members 541 to move upward to unlock the launching member 521, at this time, under the action of the launching elastic member 522, the launching member 521 moves towards the outward position and launches the toy body 51, and a plurality of toy bodies 51 are launched successively.

7. After the plurality of toy bodies 51 are launched, the child holds the spinning toy 100 with the hand and rotates the upper half part of the spinning toy 100 in the opposite direction, so that the playing method of the spinning toy 100 is further increased in the rotating process, and the energy storage part 43 is also used for storing energy in the process of rotating the spinning toy 100, so that the next launching of the toy bodies 51 is facilitated.

Other configurations of the walk-triggering spin-shooting toy 100 according to embodiments of the present invention, such as the structure and the operation principle of the energy accumulating member 41, are known to those skilled in the art and will not be described in detail herein.

In the description of the present specification, 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 (10)

1. A walk-activated projectile spinning toy comprising:

the device comprises a machine body, wherein traveling wheels are arranged on the machine body;

a rotating portion, comprising:

a rotating body rotatably coupled to the body;

the rotating lock is used for locking the rotating body at a first angle and releasing the rotating body when being triggered;

the energy storage part is connected between the machine body and the rotating body and is used for driving the rotating body to rotate towards a second angle;

the travel trigger assembly is respectively linked with the traveling wheel and the rotating locking piece, and the traveling wheel triggers the rotating locking piece to release the rotating body through the travel trigger assembly when the traveling reaches a set condition;

a transmitting section, the transmitting section comprising:

a carrier provided on at least one of the body and the rotating body, the carrier being for loading a toy body;

the launching mechanism is triggered to execute launching action when the rotating body rotates relative to the machine body, and moves from a return position to an exit position to launch the toy body when the launching action is executed.

2. The walk-activated spin-shooting toy of claim 1, wherein the stroke activation assembly comprises:

the first meshing part is connected with the travelling wheel;

the second meshing part is rotatably arranged on the machine body and meshed with the first meshing part;

the locking piece is movably arranged on the machine body between a first position and a second position, the rotating locking piece is locked at the first position, the rotating locking piece can be driven to move to the second position through the first meshing piece and the second meshing piece in sequence in the rotating process of the walking wheel, the rotating locking piece is released by the locking piece when the rotating body is at the second position, and the rotating locking piece releases the rotating body.

3. The walk-activated spin-shooting toy of claim 2, further comprising: the first sliding part is arranged on the machine body between an initial position and a final position in a sliding manner, the first sliding part is constructed to move towards the final position, the locking part is respectively matched with the first sliding part and the second meshing part, the locking part is used for locking the first sliding part at the initial position, and when the travelling wheel rotates to drive the second meshing part to rotate, the locking part is driven to release the first sliding part;

rotatory latch fitting with first slide links to each other, first slide is in when just the position rotatory latch fitting lock solid the rotator, first slide is in when the end position rotatory latch fitting release the rotator.

4. The walk-activated spin-shooting toy of claim 3, wherein the stroke activation assembly further comprises: the second sliding piece is arranged below the first sliding piece in a sliding manner, and the locking piece is respectively matched with the first sliding piece and the second sliding piece;

the second meshing piece is in linkage with the second sliding piece, and the second sliding piece moves when the second meshing piece rotates.

5. The walk-triggered rotating shooting toy according to claim 4, wherein a locking piece is arranged on the locking piece, a locking groove is arranged on the first sliding piece, the first sliding piece is located at the initial position when the locking piece is located in the locking groove, the bottom of the locking piece is matched with the second sliding piece, the second sliding piece drives the locking piece to move up and down when sliding, and the locking piece drives the locking piece to be separated from the locking groove when moving up.

6. The walk-activated spin-shooting toy of claim 4, wherein the second engaging member is provided with a cam, the cam abutting against the second glide member.

7. The walk-activated spin-shooting toy of claim 2, wherein the first engagement member is a worm gear and transition teeth are provided between the first engagement member and the second engagement member.

8. The walk-activated spin-shooting toy according to any one of claims 1 to 7, wherein the carrier carries a plurality of the toy bodies, the shooting mechanism being configured to perform a shooting action a plurality of times and to shoot one of the toy bodies off the rotator each time the shooting action is performed.

9. The walk-activated spin-shooting toy according to claim 8, wherein the shooting mechanism comprises a plurality of shooting mechanisms, each shooting mechanism comprises a shooting piece and a shooting elastic piece, the shooting part further comprises a locking mechanism for locking all the shooting pieces in the return position, each locking mechanism unlocks one shooting piece, the shooting elastic pieces drive the unlocked shooting pieces to move towards the exit position, and the rotation angles of the rotating body relative to the machine body are different when at least two shooting pieces are unlocked.

10. The walk-activated spin-shooting toy of claim 9, wherein the body is provided with a plurality of trigger protrusions, at least two of the trigger protrusions being spaced apart from each other in a circumferential direction of a cover surface of the rotating body rotating relative to the body;

the locking mechanism comprises a plurality of locking pieces for locking the plurality of the launching pieces in the return positions respectively, and the locking pieces are pushed to unlock the launching pieces when passing through the trigger protrusions.

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