CN219815258U - Induction type gyro toy - Google Patents

Abstract

The utility model relates to an induction type gyro toy, which comprises a shell, a rotating mechanism, a Hall sensor and a driving device, wherein the rotating mechanism, the Hall sensor and the driving device are arranged in the shell; the rotating mechanism is provided with a magnet unit and is used for driving the magnet unit to be rotatably arranged in the shell; the Hall sensor is arranged on one side of the rotating path of the magnet unit and is used for sensing the rotating speed signal of the magnet unit, and the Hall sensor is electrically connected with the driving device; the driving device is rotatably arranged in the shell, and the output end of the driving device movably clamps the top. The inductive gyro toy adopts a rotation induction mode to drive the gyro to continuously accelerate and store energy, and is simple and convenient to operate, so that the playing method of the gyro is more novel, interesting, convenient and attractive.

Description

Induction type gyro toy

Technical Field

The utility model relates to the technical field of toys, in particular to an induction type gyroscopic toy.

Background

Technological progress promotes the development of the children's toy industry, and various children's toys with different styles and different functions not only bring a lot of fun to the life of children, but also have great significance for early intelligence development. Wherein, the ejection toy based on the top attracts a large group of fan users by virtue of the cartoon film and the unique playing method thereof.

The existing ejection toy generally adopts a rack acceleration mode to accelerate and rotate a top, specifically firstly, the rack passes through a rotating gear, then the rack is pulled to drive the rotating gear to rotate, and then the rotating gear drives the top to rotate and accelerate. The gyro toy can only accelerate once, and the second acceleration can not be performed after the rack is pulled out, so that the gyro can not obtain more rotation potential energy; in addition, through the drive mode that the rack is accelerated, the user must adopt both hands to operate, so for the drive acceleration of top is more loaded down with trivial details, wastes time and energy, has reduced the interest of top toy.

Disclosure of Invention

Based on the above, the utility model aims to overcome the defects of the prior art, and provides the inductive gyro toy which drives the gyro to continuously accelerate and store energy in a rotation induction mode, and has simple and convenient operation, so that the playing method of the gyro is more novel, interesting, convenient and playful.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

an induction type gyroscopic toy comprises a shell, a rotating mechanism arranged in the shell, a Hall sensor and a driving device; the rotating mechanism is provided with a magnet unit and is used for driving the magnet unit to be rotatably arranged in the shell; the Hall sensor is arranged on one side of the rotating path of the magnet unit and is used for sensing a rotating speed signal of the magnet unit, and the Hall sensor is electrically connected with the driving device; the driving device is rotatably arranged in the shell, and the output end of the driving device movably clamps the top.

As an implementation mode, the rotating mechanism comprises a rotating box and a rotating gear set rotatably arranged in the rotating box, the rotating box is fixedly arranged in the shell, a gravity block is slidably arranged on the rotating box, the gravity block is in driving connection with the rotating gear set, and the magnet unit is arranged on the rotating gear set.

As one implementation mode, two sides of the rotating box are respectively provided with a guide sliding rod in a relatively parallel manner, and two sides of the gravity block are respectively sleeved on the guide sliding rods at two sides of the rotating box in a sliding manner; one side of the rotating box is provided with a first opening, at least one part of the rotating gear set extends out of the first opening of the rotating box, the gravity block is provided with a first driving rack, and the first driving rack is in transmission connection with the part of the rotating gear set extending out of the first opening in a matched mode.

As one embodiment, a second opening is formed in the other side of the rotating box, and at least one part of the rotating gear set extends out of the second opening of the rotating box; the other side of the gravity block is provided with a second driving rack, and the second driving rack is in transmission connection with the part of the rotating gear set extending out of the second opening in a matched mode.

As one embodiment, the rotation gear set includes a first driving gear, a first clutch gear and a rotation gear, the first driving gear and the rotation gear are respectively rotatably arranged in the rotation box, and at least one part of the first driving gear extends out of the first opening and is in transmission connection with the first driving rack in a matching way; the first driving gear is in meshed connection with the first clutch gear; the rotating box is provided with a first arc-shaped chute, the first clutch gear is slidably arranged in the first arc-shaped chute, when the first clutch gear slides to one end of the first arc-shaped chute close to the rotating gear, the first clutch gear is meshed with the rotating gear, and when the first clutch gear slides to other positions of the first arc-shaped chute, the first clutch gear is not contacted with the rotating gear; the magnet unit is arranged on the rotating gear.

As one embodiment, the rotating gear set further comprises a second driving gear and a second clutch gear, at least one part of the second driving gear extends out of the second opening and is in matched transmission connection with the second driving rack, and the second driving gear is in meshed connection with the second clutch gear; the rotating box is provided with a second arc-shaped chute, the second arc-shaped chute and the first arc-shaped chute are symmetrically arranged relative to the rotating gear, the second clutch gear is slidably arranged in the second arc-shaped chute, when the second clutch gear slides to the position, close to one end of the rotating gear, of the second arc-shaped chute, the second clutch gear is meshed with the rotating gear, and when the second clutch gear slides to other positions of the second arc-shaped chute, the second clutch gear is not contacted with the rotating gear.

As one embodiment, the driving device comprises a driving motor and a clamping assembly, wherein the driving motor is electrically connected with the hall sensor, and the output end of the driving motor is in driving connection with the clamping assembly; the top is movably clamped on the clamping component.

As an implementation mode, the output end of the driving motor is coaxially connected with a driving gear, the clamping assembly comprises a magnetic attraction sleeve and a driven gear, the magnetic attraction sleeve is of a cylindrical structure with one end open, a magnetic attraction unit is arranged on the inner wall of the opening of the magnetic attraction sleeve, the gyroscope is provided with a magnetic attraction convex column, the magnetic attraction convex column is matched with the shape of the inside of the opening of the magnetic attraction sleeve, and the magnetic attraction convex column is magnetically attracted on the magnetic attraction unit of the magnetic attraction sleeve; the driven gear is arranged at one end of the magnetic sleeve, which is far away from the opening of the magnetic sleeve, and the driven gear is meshed with the driving gear.

As one embodiment, the shell is a cavity structure with one end open, and the opening direction of the shell is consistent with the opening direction of the magnetic sleeve; the shell is provided with a pushing and shooting rod in a telescopic mode, one end of the pushing and shooting rod extends out of the shell, the other end of the pushing and shooting rod is arranged on the outer peripheral side of the magnetic attraction sleeve, and the pushing and shooting rod is used for pushing and shooting the top out of the opening of the shell.

As one embodiment, a return spring is provided telescopically in the interior of the housing, and the ejector pin is provided telescopically in the housing by the return spring; the driving device further comprises a power module, and the power module is electrically connected with the driving motor.

Compared with the prior art, the induction type gyroscopic toy has the beneficial effects that:

the rotating mechanism mainly swings and slides the gravity block in a swinging way, so that the gravity block continuously drives and accelerates the rotating gear set in the back and forth sliding process, and then the rotating gear set drives the magnet unit to rotate; in the rotating process of the magnet unit, the Hall sensor is used for sensing a rotating speed signal of the magnet unit, further processing the sensed rotating speed signal to output a corresponding control signal, sending the control signal to the driving motor and controlling the driving motor to rotate, driving the magnetic attraction sleeve and the gyroscope to synchronously rotate through the driving motor, and finally pushing the gyroscope after energy storage through the pushing and shooting rod. Therefore, the gyroscope is driven to rotate in an induction type driving mode, so that the operation experience of a user is enhanced, meanwhile, the gyroscope can be continuously driven to store energy, the operation is simple and convenient, and the playing method of the gyroscope is more novel, interesting, convenient and attractive.

For a better understanding and implementation, the present utility model is described in detail below with reference to the drawings.

Drawings

FIG. 1 is a schematic diagram of an inductive gyroscopic toy according to the present utility model;

FIG. 2 is a second schematic diagram of the inductive gyroscopic toy of the present utility model;

FIG. 3 is a schematic diagram of the internal structure of the inductive gyroscopic toy of the present utility model;

FIG. 4 is a second schematic diagram of the internal structure of the inductive gyroscopic toy of the present utility model;

FIG. 5 is a third schematic view of the internal structure of the inductive gyroscopic toy of the present utility model;

FIG. 6 is an exploded view of the inductive gyroscopic toy of the present utility model;

FIG. 7 is a schematic diagram of the overall structure of the rotating mechanism of the inductive gyroscopic toy of the present utility model;

FIG. 8 is a schematic view of the internal structure of the rotating mechanism of the inductive gyroscopic toy of the present utility model;

fig. 9 is a schematic structural view of a top of the inductive-type top toy of the present utility model.

Reference numerals illustrate:

10. a housing; 20. a top; 21. magnetic attraction convex columns; 30. a rotating mechanism; 31. rotating the box; 32. a guide slide bar; 33. a gravity block; 331. a first drive rack; 332. a second drive rack; 34. a first drive gear; 35. a first clutch gear; 36. rotating the gear; 37. a second drive gear; 38. a second clutch gear; 39. a transmission gear; 40. a magnet unit; 50. a hall sensor; 60. a driving device; 61. a driving motor; 62. a magnetic sleeve; 63. a drive gear; 64. a driven gear; 65. a power module; 66. a switch; 70. pushing the ejector pin.

Detailed Description

For further illustration of the various embodiments, the utility model is provided with the accompanying drawings. The accompanying drawings, which are incorporated in and constitute a part of this disclosure, illustrate embodiments and together with the description, serve to explain the principles of the embodiments. With reference to these matters, one of ordinary skill in the art will understand other possible implementations and advantages of the present utility model.

In the description of the present utility model, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "left", "right", "top", "bottom", "inner", "outer", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus are not to be construed as limiting the present utility model.

Referring to fig. 1 to 9, the present embodiment provides an inductive gyroscopic toy, which includes a housing 10, a rotation mechanism 30, a hall sensor 50 and a driving device 60, which are disposed in the housing 10; the rotating mechanism 30 is provided with a magnet unit 40, and the rotating mechanism 30 is used for driving the magnet unit 40 to be rotatably arranged in the shell 10; the hall sensor 50 is disposed at one side of the rotation path of the magnet unit 40, and the hall sensor 50 is used for sensing a rotation speed signal of the magnet unit 40, and the hall sensor 50 is electrically connected with the driving device 60; the driving device 60 is rotatably disposed in the housing 10, and an output end of the driving device 60 movably clamps the top 20.

Specifically, the rotating mechanism 30 of the present embodiment includes a rotating box 31 and a rotating gear 36 set rotatably disposed in the rotating box 31, the rotating box 31 is fixedly mounted in the housing 10, a gravity block 33 is slidably disposed on the rotating box 31, the gravity block 33 is in driving connection with the rotating gear 36 set, and the magnet unit 40 is disposed on the rotating gear 36 set.

Further, the two sides of the rotating box 31 of the embodiment are respectively provided with a guide sliding rod 32 relatively in parallel, and the two sides of the gravity block 33 are respectively sleeved on the guide sliding rods 32 at the two sides of the rotating box 31 in a sliding manner; one side of the rotating box 31 is provided with a first opening, at least one part of the rotating gear set extends out of the first opening of the rotating box 31, the gravity block 33 is provided with a first driving rack 331, and the first driving rack 331 is in transmission connection with the part of the rotating gear set extending out of the first opening.

Therefore, in this embodiment, the gravity block 33 can slide back and forth on the guide rail on the rotating box 31 by swinging the gravity block 33, and in the process of sliding the gravity block 33 back and forth, the first driving rack 331 of the gravity block 33 can drive the rotating gear set to rotate, so as to drive the magnet unit 40 to synchronously rotate; the hall sensor 50 is used for sensing the rotation speed signal of the magnet unit 40, and further processing the sensed rotation speed signal to output a corresponding control signal, wherein the control signal is sent to the driving device 60 and controls the driving device 60 to rotate, and then the driving device 60 drives the top 20 to rotate.

Further, a second opening is provided on the other side of the rotary case 31 in the present embodiment, and at least a portion of the rotary gear set extends out of the second opening of the rotary case 31; the other side of the gravity block 33 is provided with a second driving rack 332, and the second driving rack 332 is in transmission connection with a part of the rotating gear set extending out of the second opening in a matched mode.

That is, the two sides of the rotating case 31 of the present embodiment are provided with the first opening and the second opening, respectively, and the two sides of the rotating gear set are provided with the portions protruding outside the first opening and the second opening, respectively, and accordingly, the two sides of the gravity block 33 are provided with the first driving rack 331 and the second driving rack 332, respectively, thereby enabling the gravity block 33 to further improve its driving performance to the rotating gear set.

To further illustrate the structural design of the rotary gear set of the present embodiment, in the present embodiment, the rotary gear set includes a first driving gear 34, a first clutch gear 35 and a rotary gear 36, the first driving gear 34 and the rotary gear 36 are rotatably disposed in the rotary box 31, respectively, and at least a portion of the first driving gear 34 protrudes out of the first opening and is in transmission connection with the first driving rack 331 in a matching manner; the first driving gear 34 is in meshed connection with the first clutch gear 35; the rotating box 31 is provided with a first arc chute in which a first clutch gear 35 is slidably provided, and when the first clutch gear 35 slides to one end of the first arc chute near the rotating gear 36, the first clutch gear 35 is engaged with the rotating gear 36, and when the first clutch gear 35 slides to the other position of the first arc chute, the first clutch gear 35 and the rotating gear 36 are not in contact with each other. Similarly, the rotating gear set further comprises a second driving gear 37 and a second clutch gear 38, at least one part of the second driving gear 37 extends out of the second opening and is in matched transmission connection with the second driving rack 332, and the second driving gear 37 is in meshed connection with the second clutch gear 38; the rotating box 31 is provided with a second arc chute, the second arc chute and the first arc chute are symmetrically arranged relative to the rotating gear 36, the second clutch gear 38 is slidably arranged in the second arc chute, when the second clutch gear 38 slides to one end of the second arc chute close to the rotating gear 36, the second clutch gear 38 is meshed with the rotating gear 36, and when the second clutch gear 38 slides to other positions of the second arc chute, the second clutch gear 38 and the rotating gear 36 are not contacted with each other.

Therefore, the design manner of the clutch gear is adopted in the rotating gear set of the embodiment, so that the gravity block 33 can drive the rotating gear 36 in the back and forth sliding process, for example, when the gravity block 33 slides along one direction, the first driving rack 331 of the gravity block 33 drives the first driving gear 34 and the first clutch gear 35 to be sequentially meshed with the rotating gear 36, so that the first clutch gear 35 drives the rotating gear 36 to rotate, and at the moment, the second driving rack 332 of the gravity block 33 drives the second driving gear 37 to drive the second clutch gear 38 to be separated from the rotating gear 36, so as to prevent the second clutch gear 38 from reversely driving the rotating gear 36 to rotate; similarly, when the gravity block 33 slides in the opposite direction, the second clutch gear 38 drives the rotating gear 36 to rotate, and the first clutch gear 35 is separated from the rotating gear 36.

Further, the magnet unit 40 of the present embodiment is disposed on the rotation gear 36, so that when the gravity block 33 drives the rotation gear 36 to rotate, the rotation gear 36 drives the magnet unit 40 to rotate synchronously. In order to facilitate the hall sensor 50 to sense the magnet unit 40, the rotary box 31 of the present embodiment has an opening corresponding to the position of the rotary gear 36, and the hall sensor 50 is disposed at one side of the rotary path of the magnet unit 40, so that when the magnet unit 40 rotates, the hall sensor 50 can directly sense the rotation speed signal of the magnet unit 40. The hall sensor 50 is a conventional sensor structure in the art, and will not be described herein.

In addition, in order to facilitate the rational arrangement of the magnet unit 40 and the hall sensor 50, in some embodiments, the rotating gear 36 may further be engaged with a plurality of transmission gears 39, so that the magnet unit 40 is disposed on the transmission gear 39 farthest from the rotating gear 36.

Alternatively, the driving device 60 of the present embodiment includes a driving motor 61 and a clamping assembly, the driving motor 61 is electrically connected with the hall sensor 50, and an output end of the driving motor 61 is in driving connection with the clamping assembly; top 20 is movably held on the holding assembly.

Further, the output end of the driving motor 61 is coaxially connected with a driving gear 63, the clamping assembly comprises a magnetic attraction sleeve 62 and a driven gear 64, the magnetic attraction sleeve 62 is of a cylindrical structure with one end open, a magnetic attraction unit is arranged on the inner wall of the opening of the magnetic attraction sleeve 62, the gyroscope 20 is provided with a magnetic attraction convex column 21, the magnetic attraction convex column 21 is matched with the shape of the inner part of the opening of the magnetic attraction sleeve 62, and the magnetic attraction convex column 21 is magnetically attracted on the magnetic attraction unit of the magnetic attraction sleeve 62; the driven gear 64 is disposed at an end of the magnetic sleeve 62 away from the opening, and the driven gear 64 is engaged with the driving gear 63.

In addition, the housing 10 of the present embodiment has a cavity structure with one end opened, and the opening direction of the housing 10 is consistent with the opening direction of the magnetic sleeve 62; the casing 10 is telescopically provided with a push rod 70, one end of the push rod 70 extends out of the casing 10, the other end of the push rod 70 is arranged on the outer circumferential side of the magnetic sleeve 62, and the push rod 70 is used for pushing out the top 20 from the opening of the casing 10.

Wherein, the inside of the shell 10 is provided with a return spring in a telescopic way, and the ejector pin 70 is provided in the shell 10 in a telescopic way through the return spring; the driving device 60 further includes a power module 65, the power module 65 is electrically connected to the driving motor 61, and the power module 65 is used for providing power for the driving motor 61. The power module 65 of the present embodiment may adopt a rechargeable power structure or a detachable power structure, which are all conventional in the art, and will not be described herein. In addition, the driving device 60 of the present embodiment further includes a switch 66, the switch 66 is used for controlling the on-off of the driving motor 61, and the switch 66 is disposed on the outer wall of the housing 10, so as to be convenient for a user to operate.

Therefore, the rotating mechanism 30 of the utility model swings and slides the gravity block 33 mainly in a swinging manner, so that the gravity block 33 continuously drives and accelerates the rotating gear set in the back and forth sliding process, and then the rotating gear set drives the magnet unit 40 to rotate; in the process of rotating the magnet unit 40, the hall sensor 50 is used for sensing a rotation speed signal of the magnet unit 40, further processing the sensed rotation speed signal to output a corresponding control signal, sending the control signal to the driving motor 61 and controlling the driving motor 61 to rotate, further driving the magnetic sleeve 62 and the gyroscope 20 to synchronously rotate through the driving motor 61, and finally pushing the stored gyroscope 20 out through the pushing rod 70. Therefore, the utility model drives the top 20 to rotate in an inductive driving mode, thereby enhancing the operation experience of a user, simultaneously continuously driving and storing energy for the top 20, and having simple and convenient operation, and ensuring that the playing method of the top 20 is more novel, interesting, convenient and playful.

The above examples illustrate only a few embodiments of the present utility model, which are described in greater detail and are not to be construed as limiting the scope of the inventive inductive gyroscopic toy. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the utility model, which are all within the scope of the utility model.

Claims (10)

1. An inductive gyroscopic toy, comprising:

comprises a shell, a rotating mechanism arranged in the shell, a Hall sensor and a driving device; the rotating mechanism is provided with a magnet unit and is used for driving the magnet unit to be rotatably arranged in the shell; the Hall sensor is arranged on one side of the rotating path of the magnet unit and is used for sensing a rotating speed signal of the magnet unit, and the Hall sensor is electrically connected with the driving device; the driving device is rotatably arranged in the shell, and the output end of the driving device movably clamps the top.

2. The inductive gyroscopic toy of claim 1, wherein:

the rotating mechanism comprises a rotating box and a rotating gear set which is rotatably arranged in the rotating box, the rotating box is fixedly arranged in the shell, a gravity block is slidably arranged on the rotating box, the gravity block is in driving connection with the rotating gear set, and the magnet unit is arranged on the rotating gear set.

3. The inductive gyroscopic toy of claim 2, in which:

the two sides of the rotating box are respectively provided with a guide slide rod in parallel relatively, and the two sides of the gravity block are respectively sleeved on the guide slide rods at the two sides of the rotating box in a sliding manner; one side of the rotating box is provided with a first opening, at least one part of the rotating gear set extends out of the first opening of the rotating box, the gravity block is provided with a first driving rack, and the first driving rack is in transmission connection with the part of the rotating gear set extending out of the first opening in a matched mode.

4. An inductive gyroscopic toy according to claim 3, in which:

a second opening is formed in the other side of the rotating box, and at least one part of the rotating gear set extends out of the second opening of the rotating box; the other side of the gravity block is provided with a second driving rack, and the second driving rack is in transmission connection with the part of the rotating gear set extending out of the second opening in a matched mode.

5. The inductive gyroscopic toy of claim 4, wherein:

the rotating gear set comprises a first driving gear, a first clutch gear and a rotating gear, the first driving gear and the rotating gear are respectively and rotatably arranged in the rotating box, and at least one part of the first driving gear extends out of the first opening and is in matched transmission connection with the first driving rack; the first driving gear is in meshed connection with the first clutch gear; the rotating box is provided with a first arc-shaped chute, the first clutch gear is slidably arranged in the first arc-shaped chute, when the first clutch gear slides to one end of the first arc-shaped chute close to the rotating gear, the first clutch gear is meshed with the rotating gear, and when the first clutch gear slides to other positions of the first arc-shaped chute, the first clutch gear is not contacted with the rotating gear; the magnet unit is arranged on the rotating gear.

6. The inductive gyroscopic toy of claim 5, wherein:

the rotating gear set further comprises a second driving gear and a second clutch gear, at least one part of the second driving gear extends out of the second opening and is in matched transmission connection with the second driving rack, and the second driving gear is in meshed connection with the second clutch gear; the rotating box is provided with a second arc-shaped chute, the second arc-shaped chute and the first arc-shaped chute are symmetrically arranged relative to the rotating gear, the second clutch gear is slidably arranged in the second arc-shaped chute, when the second clutch gear slides to the position, close to one end of the rotating gear, of the second arc-shaped chute, the second clutch gear is meshed with the rotating gear, and when the second clutch gear slides to other positions of the second arc-shaped chute, the second clutch gear is not contacted with the rotating gear.

7. The inductive gyroscopic toy of claim 1, wherein:

the driving device comprises a driving motor and a clamping assembly, wherein the driving motor is electrically connected with the Hall sensor, and the output end of the driving motor is in driving connection with the clamping assembly; the top is movably clamped on the clamping component.

8. The inductive gyroscopic toy of claim 7, wherein:

the output end of the driving motor is coaxially connected with a driving gear, the clamping assembly comprises a magnetic attraction sleeve and a driven gear, the magnetic attraction sleeve is of a cylindrical structure with one end open, a magnetic attraction unit is arranged on the inner wall of the opening of the magnetic attraction sleeve, the gyroscope is provided with a magnetic attraction convex column, the magnetic attraction convex column is matched with the shape of the inside of the opening of the magnetic attraction sleeve, and the magnetic attraction convex column is magnetically attracted to the magnetic attraction unit of the magnetic attraction sleeve; the driven gear is arranged at one end of the magnetic sleeve, which is far away from the opening of the magnetic sleeve, and the driven gear is meshed with the driving gear.

9. The inductive gyroscopic toy of claim 8, wherein:

the shell is of a cavity structure with one end open, and the opening direction of the shell is consistent with the opening direction of the magnetic sleeve; the shell is provided with a pushing and shooting rod in a telescopic mode, one end of the pushing and shooting rod extends out of the shell, the other end of the pushing and shooting rod is arranged on the outer peripheral side of the magnetic attraction sleeve, and the pushing and shooting rod is used for pushing and shooting the top out of the opening of the shell.

10. The inductive gyroscopic toy of claim 9, wherein:

a reset spring is retractably arranged in the shell, and the ejector rod is retractably arranged in the shell through the reset spring; the driving device further comprises a power module, and the power module is electrically connected with the driving motor.