CN214633982U - Flying gyro that circles round - Google Patents

Abstract

A flying gyro comprises a shell, a driving component, a fan blade component and a shaft; the shell is of a net structure and consists of an upper shell and a lower shell; the driving assembly consists of a gearbox main body, a motor, motor teeth, a battery, a main control board seat and a positioning pipe; the center of the gearbox main body is provided with an inner cavity, and at least more than 3 propeller blades capable of generating lift force when rotating are uniformly distributed on the periphery of the inner cavity; the motor teeth are arranged on the motor, and the motor is fixed in the inner cavity of the gearbox main body; the battery is arranged in the inner cavity of the tooth box main body; the main control board is arranged on the main control board seat; the positioning pipe is arranged in the center of the gearbox main body, and the other end of the positioning pipe is arranged in the central hole of the main control plate seat; the fan blade assembly consists of fan blades and driving teeth; the shaft penetrates through the positioning pipe, two ends of the shaft are respectively installed at the centers of the upper shell and the lower shell, and the battery supplies power to the main control board.

Description

Flying gyro that circles round

Technical Field

The utility model relates to the technical field of entertainment toys, in particular to a structure device of a flying gyro.

Background

The spinning top toy is not only a toy enjoyed by children but also a toy enjoyed by adults all the time, and the spinning top toy on the market at present has various types, namely, ground-turning, flying, manual, electric and various types.

The most original top is made of wood, is large at the upper part and sharp at the lower part, is placed on the ground and is drawn by a whip, and is very popular with children. Later, an electronic spinning top was developed, which is electrically operated to rotate on the ground, and which emits not only colorful light but also sound. Some spinning tops flying in the sky, such as bamboo dragonflies, also fly back by themselves when rotating at high speed if the flying posture is appropriate.

The utility model provides a simple structure, low cost's structure only can realize the flight top effect with a motor and simple control circuit.

Disclosure of Invention

The utility model aims to solve the technical problem of providing a flying gyroscope which comprises a shell, a driving component, a fan blade component and a shaft; the shell is of a net structure and consists of an upper shell and a lower shell; the driving assembly consists of a gearbox main body, a motor, motor teeth, a battery, a main control board seat and a positioning pipe; the center of the gearbox main body is provided with an inner cavity, and at least more than 3 propeller blades capable of generating lift force when rotating are uniformly distributed on the periphery of the inner cavity; the motor teeth are arranged on the motor, and the motor is fixed in the inner cavity of the gearbox main body; the battery is arranged in the inner cavity of the tooth box main body; the main control board is arranged on the main control board seat; the positioning pipe is arranged in the center of the gearbox main body, and the other end of the positioning pipe is arranged in the central hole of the main control plate seat; the fan blade assembly consists of fan blades and driving teeth; the shaft penetrates through the positioning pipe, two ends of the shaft are respectively installed at the centers of the upper shell and the lower shell, and the battery supplies power to the main control board.

The fan blade assembly is rotatably arranged on the positioning pipe; the driving teeth drive the fan blades to rotate around the positioning pipe as a center.

The rotation direction of the fan blade is opposite to that of the propeller of the gearbox main body, and when the fan blade rotates, the fan blade and the propeller of the gearbox main body can generate thrust in the same direction.

The tail ends of the propeller blades of the gearbox main body are connected by a circle of bone positions.

The driving assembly flexibly rotates around the shaft through the positioning pipe.

The main control board is provided with a switch and a charging socket, the main control board is arranged at one end of the shaft and is close to the axis of the shaft, and the switch can be pressed or a charging head can be inserted into the charging socket through the mesh hole of the shell.

The main control plate seat can be directly arranged on the gearbox main body or arranged on a connecting piece between the main control plate seat and the gearbox main body.

The main control board is provided with a light bar, one part of the light bar is fixed on the main control board seat, and the other part of the light bar is fixed on the outermost protective bone of the tooth box main body.

The main control panel controls the rotating speed of the motor and the flashing mode of the lamp strip.

The wind blades and the gearbox main body rotate at a high speed to provide lift force for the flying gyroscopic gyroscope, the gearbox main body can generate a gyroscope effect when rotating at a high speed, and when the flying gyroscopic gyroscope is thrown out at different postures, the flying gyroscopic gyroscope can fly according to different tracks under the action of the gyroscope effect and the lift force.

Compared with the prior art, the utility model discloses a single motor realizes the top effect with the control circuit cooperation, and not only simple structure, mechanical properties is good moreover, and the low price adapts to bulk production.

Drawings

FIG. 1: is a schematic cross-sectional view of an embodiment of the present invention.

FIG. 2: is a top schematic view of an embodiment of the present invention.

FIG. 3: is an exploded view of an embodiment of the present invention.

Reference numbers for parts of the drawings:

1-a battery, wherein the battery is provided with a battery,

2-the upper shell is arranged on the shell,

3-the main control board seat is arranged on the main control board seat,

4-a switch is arranged on the base plate,

5-the axis of the shaft is as follows,

6-the main control board is connected with the main control board,

7-a charging socket is arranged on the base,

8-a main control board is pressed and covered,

9-positioning the tube, namely positioning the tube,

10-a motor, wherein the motor is provided with a motor,

11-the drive teeth are driven by the motor,

12-the main body of the tooth box,

13-a fan blade, wherein the fan blade is provided with a fan blade,

14-a lower shell, which is,

15-the amount of the tea-leaves is 15-cupola,

16-the teeth of the motor-the teeth,

17-a light bar.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings 1, 2, 3 and the embodiments.

One of the embodiments of the present invention is a structural device of a flying gyroscope with a rotary function, and the structural schematic diagram of the structural device is shown in fig. 1, fig. 2, and fig. 3. The device comprises a shell, a driving component, a fan blade component and a shaft 5, wherein the shell is of a net structure and consists of an upper shell 2 and a lower shell 14; the driving assembly consists of a gearbox main body 12, a motor 10, motor teeth 16, a battery 1, a main control board 6, a main control board seat 3 and a positioning pipe 9.

An inner cavity is formed in the center of the gearbox main body 12, 6 propeller blades capable of generating lift force when rotating are uniformly distributed on the periphery of the inner cavity, the tail ends of the propeller blades are connected through a circle of bone positions, the bone positions can not only protect the fan blades from deforming, but also can generate larger inertia when rotating at a high speed, and accordingly the gyroscopic effect of the gearbox main body 12 is stronger. The tooth box main body 12 has a hole in the center thereof, and the positioning tube 9 is mounted in the hole, and the tooth box main body 12 can rotate around the axis of the positioning tube 9. The motor teeth 16 are mounted on the motor 10, and the motor 10 is fixed in the inner cavity of the gear box main body 12. The battery 1 is arranged in the inner cavity of the gearbox main body 12, and the battery 1 supplies power to the main control board 6.

The main control board 6 is a circular circuit board, the middle of which is provided with a hole, is arranged on the main control board seat 3 and is pressed by the main control board pressing cover 8. The main control board 3 is provided with a switch 4 and a charging socket 7, the main control board 3 is arranged at one end of the shaft 5 and is close to the axis position of the shaft 5, and a hole is formed in the middle of the main control board 3 and is used for installing the positioning tube 9. The main control board is mounted on the gearbox body 12. The shell is of a net structure and mainly has the functions of ventilating and reducing weight, and when the flying gyro is in flight, airflow generated by rotation of the propeller and the fan blades 13 of the gearbox main body 12 can flow out through the meshes. The shaft 5 is installed at the center of the upper case 2 and the lower case 14 coaxially with the entire case. The upper shell 2 is provided with a reticular hole close to the shaft 5, and the switch 5 can be pressed through the reticular hole, so that the effect of starting or stopping the machine is achieved; the flying gyroscopic gyroscope can also be charged by inserting a charging head into the charging socket 7.

The positioning tube 9 penetrates through the middle of the gearbox main body 12 and the main control plate 6 to ensure that the gearbox main body 12 and the main control plate seat 6 are kept in a concentric condition when rotating at a high speed. The fan blade 13 is arranged on the driving tooth 11, the driving tooth 11 is arranged on the positioning pipe 9 and can rotate around the positioning pipe 9, and the driving tooth 11 is meshed with the motor tooth 16. When the motor 10 works, the driving teeth 11 are driven to rotate through the motor teeth 16, and then the fan blades 13 are driven to rotate at a high speed to generate thrust. Under the action of the torque force of the fan blades 13, the motor 10 drives the gearbox main body 12 to rotate around the shaft 5 in the opposite direction, so that the propeller on the gearbox main body 12 also generates thrust. A cupola 15 is provided between the drive teeth 11 and the lower shell to prevent the gearbox body 12 from moving up and down on the shaft 5 during rotation.

The light bar 17 is a flexible circuit board, and a 1ed lamp capable of emitting colored light is pasted on the flexible circuit board. One end of the light bar 17 is electrically connected to the main control board 6, and a part away from the main control board 6 is fixed on the main control board seat 3, and another part is fixed on the outermost bone position of the tooth box main body 12, so that the light bar 17 can be lengthened according to the design requirement, and the other end is fixed on the cup 15.

The main control board seat 3 can also be arranged on a connecting piece between the gearbox main bodies according to the design requirement.

The shell can be designed into a net body with various shapes according to design requirements, but the shell needs to be light, and the net hole can ensure that airflow can smoothly flow out instead of resistance, so that the flying gyro is difficult to fly.

The working principle of the flying gyro is as follows: the battery 1 supplies power to the main control board 6, and the main control board 6 is provided with an inductor or a receiver to receive an external command, thereby controlling the operation of the motor 10. When the motor 10 drives the fan blade 13 to rotate at a high speed, the gearbox main body 12 rotates in the opposite direction, the propeller of the gearbox main body 12 generates thrust, and the directions of the two thrust are parallel to the axis of the shaft 5. The two thrusts push up the flying gyroscopic gyroscope together. Depending on the initial conditions of the flying gyros, it may produce various flight effects, of which the following are only a few.

When the axis of the shaft 5 of the gyro is vertical to the ground, the thrust of the gyro is changed into a lift force. If the lift force is the same as the weight of the aircraft, the aircraft can fly in the air in a suspended mode; if the lift is greater than its weight, it will fly upwards; if the lift is less than its weight, it will fly downward.

When the axis of the shaft 5 of the flying gyroscopic gyroscope is at an angle to the ground, a portion of its thrust force becomes a lift force to balance its weight, and a horizontal component force is generated which pushes the flying gyroscopic gyroscope in a direction opposite to the component force.

When the axis of the shaft 5 of the flying gyro forms an angle with the ground, the flying gyro is thrown out by force, the throwing direction is different, different flying effects can be generated, and if the throwing direction is consistent with the component force pushing direction, the flying gyro flies towards the component force pushing direction; if the throwing direction is opposite to the component force direction, the flying robot flies for a period of time towards the throwing direction because of inertia, and flies towards the component force pushing direction because of the action of the component force, namely flies back; if the throwing direction is not consistent with the component force pushing direction, various effects can be generated, and the flying robot flies forwards and leftwards, spins forwards and rotates backwards and spins forwards and leftwards by artificial reference.

The apparatus and method of the present invention have been described in what is presently considered to be the most practical and preferred embodiment. It should be noted that the present invention is not limited by the above disclosed embodiments. It is intended that all such similar constructions and modifications be included within the spirit and scope of the invention as defined in the appended claims and that such scope be accorded the broadest interpretation so as to encompass all such similar constructions and modifications.

Claims (10)

1. A flying gyroscopic gyroscope characterized by: the fan blade assembly comprises a shell, a driving assembly, a fan blade assembly and a shaft; the shell is of a net structure and consists of an upper shell and a lower shell; the driving assembly consists of a gearbox main body, a motor, motor teeth, a battery, a main control board seat and a positioning pipe; the center of the gearbox main body is provided with an inner cavity, and at least more than 3 propeller blades capable of generating lift force when rotating are uniformly distributed on the periphery of the inner cavity; the motor teeth are arranged on the motor, and the motor is fixed in the inner cavity of the gearbox main body; the battery is arranged in the inner cavity of the tooth box main body; the main control board is arranged on the main control board seat; the positioning pipe is arranged in the center of the gearbox main body, and the other end of the positioning pipe is arranged in the central hole of the main control plate seat; the fan blade assembly consists of fan blades and driving teeth; the shaft penetrates through the positioning pipe, two ends of the shaft are respectively installed at the centers of the upper shell and the lower shell, and the battery supplies power to the main control board.

2. A flying spinning top according to claim 1, wherein: the fan blade assembly is rotatably arranged on the positioning pipe; the driving teeth drive the fan blades to rotate around the positioning pipe as a center.

3. A flying spinning top according to claim 1, wherein: the rotation direction of the fan blade is opposite to that of the propeller of the gearbox main body, and when the fan blade rotates, the fan blade and the propeller of the gearbox main body can generate thrust in the same direction.

4. A flying spinning top according to claim 3, wherein: the tail ends of the propeller blades of the gearbox main body are connected by a circle of bone positions.

5. A flying spinning top according to claim 1, wherein: the driving assembly flexibly rotates around the shaft through the positioning pipe.

6. A flying spinning top according to claim 1, wherein: the main control board is provided with a switch and a charging socket, the main control board is arranged at one end of the shaft and is close to the axis of the shaft, and the switch can be pressed or a charging head can be inserted into the charging socket through the mesh hole of the shell.

7. A flying spinning top according to claim 1, wherein: the main control plate seat is installed on the gearbox main body.

8. A flying spinning top according to claim 1, wherein: the main control board is provided with a light bar, one part of the light bar is fixed on the main control board seat, and the other part of the light bar is fixed on the outermost protective bone of the tooth box main body.

9. A flying spinning top according to claim 8, wherein: the main control panel controls the rotating speed of the motor and the flashing mode of the lamp strip.

10. A flying spinning top according to claim 1, wherein: the wind blades and the gearbox main body rotate at a high speed to provide lift force for the flying gyroscopic gyroscope, the gearbox main body can generate a gyroscope effect when rotating at a high speed, and when the flying gyroscopic gyroscope is thrown out at different postures, the flying gyroscopic gyroscope can fly according to different tracks under the action of the gyroscope effect and the lift force.

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