CN221618574U - Automatic lifting device of simulation toy - Google Patents

Abstract

The utility model provides an automatic lifting device of a simulation toy, which comprises a suspension piece, a rope, a winding mechanism, a driving mechanism and a supporting platform; the winding mechanism comprises a first main shaft vertically connected with the supporting platform, a connecting piece, a first gear assembly and a winding assembly are fixedly connected to the outside of the first main shaft from top to bottom, and the winding assembly is connected with the hanging piece through a rope; the driving mechanism comprises a driving motor and a second gear assembly, and the driving motor drives the second gear assembly to rotate. The utility model has the advantages that the simulated toy is hung on the wall through the hanging piece, when the sound control is received, the winding mechanism pays off, and the simulated toy automatically descends; when the toy falls to the lowest point, the driving mechanism drives the winding mechanism to wind up, the simulation toy automatically rises, the climbing habit of the simulation toy can be truly simulated, the simulation degree is improved, and the toy is high and interesting.

Description

Automatic lifting device of simulation toy

[ Field of technology ]

The utility model relates to the technical field of toys, in particular to an automatic lifting device of a simulation toy.

[ Background Art ]

Children like animal toys, particularly animal toys with higher simulation degree, can attract the attention of children. However, animal toys are currently available on the market, which generally only simulate animal forms and cannot simulate animal actions. If the spider toy is on the market, the spider toy is only similar in shape, only takes the decoration and the hand grip play effect, but has poor mobility, and influences the interestingness of the toy; moreover, the spiders belong to animals which like to climb the wall, but the existing spiders toy can only be used for playing on the ground, and cannot truly embody the living characteristics of the spiders, so that the simulation degree is not high, and the interestingness is further influenced.

For example, the prior art CN 204107036U discloses a crawling mechanism of a simulated crawling toy, although the simulated crawling toy can simulate crawling on the ground, the automatic lifting function cannot be realized, so that the simulated crawling toy cannot truly simulate the habit of animals, and the simulation degree is low and the interestingness is not high.

In view of this, the present inventors have conducted intensive studies on the above problems, and have produced the present invention.

[ utility model ]

The utility model provides an automatic lifting device which can enable a simulation toy to automatically lift and improve the simulation degree and the interestingness.

The utility model is realized in the following way: an automatic lifting device of a simulation toy comprises a suspension member, a rope, a winding mechanism, a driving mechanism and a supporting platform;

The winding mechanism is arranged at the rear end of the supporting platform and comprises a first main shaft vertically connected with the supporting platform, a connecting piece, a first gear assembly and a winding assembly are fixedly connected to the outside of the first main shaft from top to bottom, and the winding assembly is connected with the hanging piece through a rope;

The driving mechanism is arranged at the front end of the supporting platform and comprises a driving motor and a second gear assembly, the driving motor drives the second gear assembly to rotate, and when the second gear assembly is meshed with the first gear assembly in a meeting mode, the first gear assembly is driven to rotate, and then the winding assembly is driven to rotate for winding.

Further, the first gear assembly includes a first fixed gear and a first eccentric gear; the connecting piece is provided with a through hole for the first main shaft to pass through, the connecting piece is downwards provided with a first connecting rod connected with the axis of the first eccentric gear, and the first fixed gear is fixed on the first main shaft and is meshed and connected with the first eccentric gear.

Further, a stretching assembly is arranged on the supporting platform and comprises a stretching support and an elastic piece; the connecting piece is downwards provided with a second connecting rod, one end of the elastic piece is connected with the stretching support, and the other end of the elastic piece is connected with the second connecting rod.

Further, the winding assembly comprises a first rotary table and a second rotary table which are arranged up and down, and a winding cavity is formed between the first rotary table and the second rotary table.

Further, the winding assembly further comprises a retaining wall, and the retaining wall is fixedly arranged above the supporting platform and surrounds the winding cavity.

Further, the second gear assembly comprises a second main shaft which is vertically connected with the supporting platform, and the second main shaft is positioned between the driving motor and the first main shaft; the top end of the second main shaft is fixedly connected with a first gear unit which is in meshed connection with an output gear assembly of the driving motor; the lower part of the second main shaft is fixedly connected with a second fixed wheel and an eccentric block, the eccentric block is rotationally connected with a second eccentric wheel, and the second eccentric wheel is in meshed connection with the second fixed wheel.

Further, the device also comprises a buffer gear which is arranged above the supporting platform and positioned on the rotating path of the second eccentric wheel.

Further, the buffer gear is located between the second spindle and the drive motor.

Further, the device also comprises a top cover arranged above the winding mechanism and the driving mechanism, and the first main shaft is rotationally connected with the top cover.

Further, the toy also comprises a sound control mechanism and a signal transmission mechanism which are arranged in the simulation toy.

The utility model has the advantages that: the automatic lifting device of the simulation toy can realize the automatic lifting of the simulation toy through sound control; the simulation toy is hung on a wall through a hanging piece, and when sound control is received, the winding mechanism pays off, and the simulation toy automatically descends; when the toy falls to the lowest point, the driving mechanism drives the winding mechanism to wind up, and the simulation toy automatically rises, so that the wall climbing habit of the simulation toy can be truly simulated, and the simulation toy is high in simulation degree and high in interestingness.

[ Description of the drawings ]

The utility model will be further described with reference to examples of embodiments with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of an automatic lifting device in a first embodiment.

FIG. 2 is a second schematic diagram of an automatic lifting device according to the first embodiment.

Fig. 3 is a schematic structural diagram of a connection relationship between a winding mechanism and a driving mechanism in the first embodiment.

Fig. 4 is a schematic structural view of a connector in the first embodiment.

Fig. 5 is a schematic view of the structure of the first eccentric gear and the second eccentric gear in the first embodiment.

Fig. 6 is a plan view of the first eccentric gear and the second eccentric gear in the first embodiment.

Fig. 7 is a schematic diagram of the internal structure of the simulated spider toy in the second embodiment.

Fig. 8 is a schematic diagram of the external structure of the simulated spider toy in the second embodiment.

Head 100, torso 200, suspension 300, cord 400,

The winding mechanism 1, the first main shaft 11, the connecting piece 12, the through hole 121, the first connecting rod 122, the second connecting rod 123, the clamping hook protrusion 124, the first protrusion 125, the second protrusion 126, the first gear assembly 13, the first fixed gear 131, the first eccentric gear 132, the winding assembly 14, the first rotary disk 141, the second rotary disk 142, the winding cavity 143, the retaining wall 144, the second rotary disk,

The driving mechanism 2, the driving motor 21, the second gear assembly 22, the second main shaft 221, the first gear unit 222, the second fixed wheel 223, the eccentric block 224, the second eccentric wheel 225, the output gear assembly 23,

A supporting platform 3,

A stretching assembly 4, a stretching support 41, an elastic member 42,

A buffer gear 5,

Top cover 6,

A sound control mechanism 7,

And a signal transmission mechanism 8.

[ Detailed description ] of the invention

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments. All other embodiments, based on the embodiments of the utility model, which are apparent to those of ordinary skill in the art without inventive faculty, are intended to be within the scope of the utility model. Thus, the following detailed description of the embodiments of the utility model, as presented in the figures, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model. All other embodiments, based on the embodiments of the utility model, which are apparent to those of ordinary skill in the art without inventive faculty, are intended to be within the scope of the utility model.

Referring to fig. 1, the toy simulation of the present utility model includes a head 100 and a torso 200. For convenience of description and understanding, in the following description of the present utility model, it is specified that "front" means the orientation of the head on the side of the simulated toy, and "rear" means the orientation of the torso on the side of the simulated toy. The simulated toy of the utility model can be animals like spiders, cockroaches, geckos and the like which prefer to climb the wall.

Example 1

Referring to fig. 1 to 8, the present embodiment provides an automatic lifting device for a toy simulator, which is mounted on a trunk 200. The automatic lifting device comprises a suspension 300, a rope 400, a winding mechanism 1, a driving mechanism 2 for driving the winding mechanism 1 to take up and pay out, and a supporting platform 3. The suspension 300 is a conventional suction cup, hook, suspension loop, adhesive, or the like. The simulation toy is a sound control simulation toy, and the sound control component is arranged in the simulation toy. One end of the string 400 is connected to the hanger 300, and the other end is connected to the winding mechanism 1. In the initial state, the hanger 300 hangs the artificial toy on a wall, a roof, a ceiling, etc., with the head body 100 of the artificial toy facing the ground.

The automatic lifting device can realize the automatic lifting of the simulation toy through sound control. The simulation toy is hung on a wall through the hanging piece 300, and when the sound control is received, the winding mechanism 1 pays off, and the simulation toy automatically descends; when the toy descends to the lowest point, the driving mechanism 2 drives the winding mechanism 1 to wind up, and the simulation toy automatically ascends, so that the wall climbing habit of the simulation toy can be truly simulated, and the simulation toy is high in simulation degree and high in interestingness.

The winding mechanism 1 is arranged at the rear end of the supporting platform 3, the winding mechanism 1 comprises a first main shaft 11 vertically connected with the supporting platform 3, a connecting piece 12, a first gear assembly 13 and a winding assembly 14 are fixedly connected to the outside of the first main shaft 11 from top to bottom, and the winding assembly 14 is connected with a hanging piece through a rope. The first gear component 13 is driven by the driving mechanism 2 to rotate, drives the first main shaft 11 to rotate, and further drives the winding component 14 to rotate for winding, so that the simulation toy rises.

The driving mechanism 2 is arranged at the front end of the supporting platform 3, the driving mechanism 2 comprises a driving motor 21 and a second gear assembly 22, the driving motor 21 drives the second gear assembly 22 to rotate, and when the second gear assembly 22 is meshed with the first gear assembly 13, the first gear assembly 13 is driven to rotate, and then the winding assembly 14 is driven to rotate for winding.

The first gear assembly 13 includes a first fixed gear 131, a first eccentric gear 132, and a connecting member 12; the connecting piece 12 is formed with a through hole 121 through which the first spindle 11 passes, the connecting piece 12 is formed with a first connecting rod 122 connected with the axis of the first eccentric gear 132 downwards, and the first fixed gear 131 is meshed with the first eccentric gear 132. The connecting member 12 is formed with a first protrusion 125 and a second protrusion 126, the through hole 121 is formed on the first protrusion 125, and the first connecting rod 122 is formed on the second protrusion 126.

The support platform 3 is provided with a stretching assembly 4, and the stretching assembly 4 comprises a stretching support 41 and an elastic piece 42; the connecting member 12 is further formed with a second connecting rod 123 downward, and one end of the elastic member 42 is connected to the stretching supporting seat 41, and the other end is connected to the second connecting rod 123. Preferably, the elastic member 42 is a spring, and the tension support 41 is used for fixing one end of the spring. The end of the second connecting rod 123 is formed with a hook protrusion 124, and the other end of the spring is hooked on the hook protrusion 124, so as to avoid the disengagement of the spring. When the second eccentric wheel 225 of the second gear assembly 22 presses the first eccentric gear 132, the first eccentric gear 132 and the first connecting rod 122 drive the connecting piece 12 to rotate, and then the second connecting rod 123 pulls the spring backwards, so that the second eccentric wheel 225 and the first eccentric gear 132 are disengaged, and finally the spring returns to drive the connecting piece 12 to return.

The winding assembly 14 includes a first turntable 141 and a second turntable 142 disposed up and down, and a winding cavity 143 is formed between the first turntable 141 and the second turntable 142. The arrangement of the first and second turntables 141 and 142 allows the cord to be received in the winding cavity 143, preventing the cord from being caught on the first fixed gear 131 or the first eccentric gear 132, and thus preventing the winding assembly 14 from rotating.

The winding assembly 14 further comprises a retaining wall 144, and the retaining wall 144 is fixedly arranged above the supporting platform 3 and encloses the winding cavity 143, so that the problems of contact, twisting, shell blocking and the like with other components in the wire winding and unwinding process are further guaranteed.

The second gear assembly 22 comprises a second main shaft 221 vertically connected with the support platform 3, and the second main shaft 221 is positioned between the driving motor 21 and the first main shaft 11; the top end of the second main shaft 221 is fixedly connected with a first gear unit 222, and the first gear unit 222 is in meshed connection with the output gear assembly 23 of the driving motor 21; the lower part of the second main shaft 221 is also fixedly connected with a second fixed wheel 223 and an eccentric block 224, the eccentric block 224 is rotationally connected with a second eccentric wheel 225, and the second eccentric wheel 225 is in meshed connection with the second fixed wheel 223. When the driving motor 21 is started, the output gear assembly 23 is driven to rotate, and then the second main shaft 221, the second fixed wheel 223 and the eccentric block 224 are driven to rotate, and the second eccentric wheel 225 is driven by the eccentric block 224 to do circular motion with the second main shaft 221 as the axis.

Also included is a buffer gear 5 disposed above the support platform 3 and located in the path of rotation of the second eccentric 225. The buffer gear 5 can increase the time length of the second eccentric wheel 225 doing a circle of circular motion, and control the time length of a circle to 2-3 seconds, so as to ensure complete paying-off and avoid too fast rotation.

The buffer gear 5 is located between the second main shaft 221 and the driving motor 21. The structure distribution is reasonable, and the interference with other parts is avoided.

The device also comprises a top cover 6 arranged above the winding mechanism 1 and the driving mechanism 2, and the first main shaft 11 and the second main shaft 221 are both in rotary connection with the top cover 6. The top cover 6 also has a dust-proof effect.

Also comprises a sound control mechanism 7 and a signal transmission mechanism 8 which are arranged inside the simulation toy. The installation positions of the sound control mechanism 7 and the signal transmission mechanism 8 can be flexibly adjusted according to actual requirements.

Working principle:

When the simulated toy is hung, the hanging piece 300 hangs the simulated toy on a wall, a roof, a ceiling and the like, the head 100 faces the ground, the wire rope is completely wound in the winding cavity 143 at the moment when the initial driving motor 21 is not in working state, and the hanging piece just abuts against the winding assembly 14, so that the winding assembly 14 does not rotate. Referring to the perspective of fig. 6, the second eccentric 225 of the second gear assembly 22 and the first eccentric 132 of the first gear assembly 13 are also just meshed together, which also provides a resistance to the rotation of the wire winding assembly 14 to avoid the rotation of the wire winding assembly 14. When the sound control mechanism 7 receives the sound signal, the driving motor 21 starts to operate, the output gear assembly 23 drives the second gear assembly 22 to rotate clockwise, at this time, a clockwise force is suddenly generated, the second eccentric wheel 225 is forced to rotate and press the first eccentric gear 132, so that the connecting piece 12 has a tendency to rotate anticlockwise, then the second connecting rod 123 of the connecting piece 12 stretches the elastic piece 42 backwards (the view angle of fig. 6 can be understood as right), drives the first eccentric gear 132 to rotate anticlockwise, finally the second eccentric wheel 225 is disengaged from the engagement connection with the first eccentric gear 132 to start rotating clockwise, at the same time, the elastic piece 42 is rebounded and reset, at this time, the winding assembly 14 loses resistance and starts paying out, and the simulated toy falls downwards. During paying-off, the second eccentric wheel 225 rotates clockwise by taking the second main shaft 221 as an axis, and encounters the buffer gear 5 during rotation and is meshed with the buffer gear 5 to rotate for one circle. When the second eccentric wheel 225 meets the first eccentric gear 132 again, representing that the second eccentric wheel 225 rotates for one circle, the line is paid out completely, and the simulated toy is at the lowest point; when the second eccentric wheel 225 and the first eccentric gear 132 are meshed again, the first eccentric gear 132 drives the first fixed gear 131 to rotate, so as to drive the first main shaft 11 and the winding assembly 14 to rotate for winding, and then the simulated toy rises.

Example two

Referring to fig. 1-8, the present embodiment provides a simulated spider toy, using the automatic lifting device of the first embodiment.

The simulation spider toy comprises a base, and the automatic lifting device is arranged on the base.

While specific embodiments of the utility model have been described above, it will be appreciated by those skilled in the art that the specific embodiments described are illustrative only and not intended to limit the scope of the utility model, and that equivalent modifications and variations of the utility model in light of the spirit of the utility model will be covered by the claims of the present utility model.

Claims (10)

1. An automatic lifting device of a simulation toy is characterized in that: comprises a suspension part, a rope, a winding mechanism, a driving mechanism and a supporting platform;

The winding mechanism is arranged at the rear end of the supporting platform and comprises a first main shaft vertically connected with the supporting platform, a connecting piece, a first gear assembly and a winding assembly are fixedly connected to the outside of the first main shaft from top to bottom, and the winding assembly is connected with the hanging piece through a rope;

The driving mechanism is arranged at the front end of the supporting platform and comprises a driving motor and a second gear assembly, the driving motor drives the second gear assembly to rotate, and when the second gear assembly is meshed with the first gear assembly in a meeting mode, the first gear assembly is driven to rotate, and then the winding assembly is driven to rotate for winding.

2. The automatic lifting device of a simulated toy according to claim 1, wherein: the first gear assembly comprises a first fixed gear and a first eccentric gear; the connecting piece is provided with a through hole for the first main shaft to pass through, the connecting piece is downwards provided with a first connecting rod connected with the axis of the first eccentric gear, and the first fixed gear is fixed on the first main shaft and is meshed and connected with the first eccentric gear.

3. The automatic lifting device of a simulated toy according to claim 2, wherein: the support platform is provided with a stretching assembly, and the stretching assembly comprises a stretching support and an elastic piece; the connecting piece is downwards provided with a second connecting rod, one end of the elastic piece is connected with the stretching support, and the other end of the elastic piece is connected with the second connecting rod.

4. An automatic lifting device of a simulated toy as claimed in claim 3, wherein: the winding assembly comprises a first turntable and a second turntable which are arranged up and down, and a winding cavity is formed between the first turntable and the second turntable.

5. The automatic lifting device of a simulated toy according to claim 4, wherein: the winding assembly further comprises a retaining wall, and the retaining wall is fixedly arranged above the supporting platform and surrounds the winding cavity.

6. An automatic lifting device of a simulated toy according to any of claims 1-5, wherein: the second gear assembly comprises a second main shaft which is vertically connected with the supporting platform, and the second main shaft is positioned between the driving motor and the first main shaft; the top end of the second main shaft is fixedly connected with a first gear unit which is in meshed connection with an output gear assembly of the driving motor; the lower part of the second main shaft is fixedly connected with a second fixed wheel and an eccentric block, the eccentric block is rotationally connected with a second eccentric wheel, and the second eccentric wheel is in meshed connection with the second fixed wheel.

7. The automatic lifting device of a simulated toy according to claim 6, wherein: the buffer gear is arranged above the supporting platform and positioned on the rotating path of the second eccentric wheel.

8. The automatic lifting device of a simulated toy according to claim 7, wherein: the buffer gear is located between the second spindle and the drive motor.

9. The automatic lifting device of a simulated toy of claim 8, wherein: the first main shaft is rotatably connected with the top cover.

10. The automatic lifting device of a simulated toy of claim 9, wherein: the toy also comprises a sound control mechanism and a signal transmission mechanism which are arranged in the simulation toy.