ROTARY FLYING BALL

Abstract

A rotary flying ball includes a main housing, a bracket, a paddle, a main control board, a power supply, a motor, and a lamp strip; the housing is spherical with an accommodation space therein and multiple holes thereon, the multiple holes are communicated with the accommodation space. The bracket is mounted in the accommodation space, the bracket provides a shaft, a center of the shaft coincides with a center of the main housing. The paddle is located in the accommodating space and rotatably disposed on the shaft; the main control board, the power supply, the motor, and the lamp strip are mounted on the bracket; the power supply, the motor, and the lamp strip are electrically connected to the main control board, the motor drives the paddle to rotate.

Description

FIELD OF THE DISCLOSURE

The present disclosure involves the technical field of toys, more particularly a rotary flying ball.

BACKGROUND OF THE DISCLOSURE

With the increasing emphasis on intelligent life, various related technologies of aerodynamic aircraft have been widely used in the toy technical field, creating various types of aircraft.

At present, there are various kinds of aircraft on the market, with different functions and styles, however, their control mechanisms are basically the same. And the takeoff and the flight direction of the aircraft can be controlled by the remote control. Of course, there are some kinds of intelligent aircraft, their flight direction in flight process is controlled by multiple sensors such as infrared sensors thereon, using the sensors to scan the obstacles around them, and then control or change the flight direction of the aircraft.

In the prior art, the flight control of the aircraft needs to use multiple sensors or scanning sensors, which has the defects in complex structure and difficult operation.

SUMMARY OF THE DISCLOSURE

The object of the present disclosure is to provide a type of rotary flying ball that can effectively solve the problems of complex structure and difficult operation of the aircraft in the prior art.

To achieve the above object, the present disclosure provides the following technical schemes:

A rotary flying ball includes a main housing, a bracket, a paddle, a main control board, a power supply, a motor, and a lamp strip; the housing is spherical, the housing is provided with an accommodation space therein and multiple holes communicated with the accommodation space on a wall of the housing. The bracket is mounted in the accommodation space, the bracket provides a shaft, a central of which coincides with a center of the main housing. The paddle is located in the accommodating space and rotatably disposed on the shaft; the main control board, the power supply, the motor, and the lamp strip are mounted on the bracket, the power supply, the motor and the lamp strip are electrically connected to the main control board, which rotates the paddle.

Preferably, the bracket includes a lower seat, a motor cover, an upper seat, and a pressure cover; the motor cover is fixed with the lower seat to enclose a first cavity, where the power supply and the motor are arranged; the upper seat is fixed on the motor cover, the pressure cover is fixed with the upper seat to enclose a second cavity, where the main control board is mounted, and the shaft passes the first cavity and the second cavity.

Preferably, a periphery of the lower seat provides a plurality of the first rotating blades spaced around a periphery of the shaft, with hollow areas between adjacent rotating blades.

Preferably, the paddle provides a plurality of the second rotating blades along an upper and down direction of the main housing, the second rotating blades and the first rotating blades are arranged obliquely respectively, and the inclined direction of the first rotating blades and that of the second rotating blades are opposite.

Preferably, the first rotating blades are arranged in a curved shape along the periphery of the shaft, and the plurality of the first rotating blades are curved in the same direction.

Preferably, the bracket has a rack with one end fixed with the pressure cover, both ends of the shaft are fixedly connected with an upper side and a bottom side of the housing respectively, and both ends of the rack are sleeved at both ends of the shaft respectively. The lamp strip is fixed on an outer surface of the rack.

Preferably, an outer surface of the rack is provided with a fixing groove, the lamp strip is a soft LED lamp strip fixed in the fixing groove.

Preferably, the shaft provides a drive gear, the paddle is fixedly sleeved with the drive gear, an output shaft of the motor is fixed with an active gear engaged with the drive gear.

Preferably, the housing includes an upper cover and a lower cover, which are fastened and enclosed to form the aforementioned accommodation space, the upper cover, and the lower cover are hollowed out to form the aforementioned holes communicated with the accommodation space.

Preferably, the main control board provides a main control chip connected with an acceleration sensor feedback signal to the main control chip, the main control chip controls the motor to rotate.

Compared with the prior art, the present disclosure has the following advantages and effects, specifically, from the above technical schemes, we can understand that:

The rotary flying ball is designed as a ball shape and uses the motor to drive the paddle to rotate; when the rotary flying ball is thrown out, it flies steadily in the air at the thrown angle. Under the function of the external force thrown, the rotary flying ball flies a distance in the direction thrown, then, because of the gyro effect produced by the rotation of the bracket and the paddle, the flight angle of the rotary flying ball remains constant and the rotary flying ball continues to fly in the direction of that angle. Users can preset the throwing angles of the rotary flying ball, thereby obtaining different flight trajectories, no remote control is required to control the flight trajectories. Users can throw the rotary flying ball according to the presetting angles to obtain the presetting flight trajectories, and the rotary flying ball can fly stably and instantly in the air. The rotary flying ball is simple in structure and easy to operate. At the same time, with the lamp strip, the rotary flying ball can form a cool lighting effect.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to more clearly explain the structural characteristics and functions of the disclosure, the disclosure is explained in detail combined with the accompanying drawings and specific embodiments:

FIG. 1 shows a perspective view of the preferred embodiment according to the present disclosure.

FIG. 2 shows the other perspective view of the preferred embodiment at the other anger according to the present disclosure.

FIG. 3 shows the exploded view of the preferred embodiment at the other anger according to the present disclosure.

FIG. 4 shows the other exploded view of the preferred embodiment at the other anger according to the present disclosure.

FIG. 5 shows the section view of the preferred embodiment according to the present disclosure.

EMBODIMENTS

Referring to FIG. 1-5, a rotary flying ball includes a main housing 10, a bracket 20, a paddle 30, a main control board 40, a power supply 50, a motor 60, and a lamp strip 70.

The housing 10 is spherical, the housing 10 is provided with an accommodation space 101 therein and multiple holes 102 communicated with the accommodation space on a wall of the housing 10. Specifically, the housing 10 includes an upper cover 11 and a lower cover 12, which are fastened and easy to operate and conducive to subsequent maintenance. The upper cover 11 and the lower cover 12 are enclosed to form the accommodation space 101, the upper cover 11 and the lower cover 12 are hollowed out to form the holes 102 communicated with the accommodation space 101.

The bracket 20 is mounted in the accommodation space 101, the bracket 20 provides a shaft 81. A central of the shaft 81 coincides with a center of the housing 10, which avoids eccentricity and interference to the self-stability of the rotary flying ball, and ensures that the flight trajectory of the rotary flying ball can be judged. Specifically, in the embodiment, the bracket 20 includes a lower seat 21, a motor cover 22, an upper seat 23, and a pressure cover 24. The motor cover 22 is fixed with the lower seat 21 to enclose a first cavity 201, the upper seat 23 is fixed on the motor cover 22, and the pressure cover 24 is fixed with the upper seat 23 to enclose a second cavity 202. And, a periphery of the lower seat 21 provides a plurality of the first rotating blades 203 spaced around a periphery of the shaft 81, there are hollow areas 204 between the adjacent rotating blades 203. The first rotating blades 203 are arranged in a curved shape along the periphery of the shaft 81, and the plurality of the first rotating blades 203 are curved in the same direction so that the first rotating blades 203 rotate to produce a large downward wind; and, the bracket 20 has a rack 25 with one end fixed with the pressure cover 24, both ends of the shaft 81 are fixedly connected with an upper side and a bottom side of the housing 10, respectively, and both ends of the rack 25 are sleeved at both ends of the shaft 81, respectively.

The paddle 30 is located in the accommodating space 101 and rotatably disposed on the shaft 81; the paddle 30 provides a plurality of the second rotating blades 31 along an upper and down direction of the main housing 10, the second rotating blades 31 and the first rotating blades 203 are arranged obliquely, respectively, and the inclined direction of the first rotating blades 203 and those of the second rotating blades 31 are opposite.

The main control board 40, the power supply 50, the motor 60, and the lamp strip 70 are mounted on the bracket 20. The power supply 50, the motor 60, and the lamp strip 70 are electrically connected to the main control board 40, the motor 60 drives the shaft 81 to rotate.

In the embodiment, the main control board 40 provides a main control chip 41 connected with an acceleration sensor 42 feedback signal to the main control chip 41, the main control chip 41 controls the motor 60 to rotate. The power supply 50 and the motor 60 are arranged in the first cavity 20, the main control board 40 is fixed in the second cavity 202, and the shaft 81 passes the first cavity 201 and the second cavity 202. The shaft 81 provides a drive gear 83, the paddle 30 is fixedly sleeved with the drive gear 82, an output shaft 61 of the motor 60 is fixed with an active gear 83 engaged with the drive gear 82. Additionally, the lamp strip 701 is fixed on an outer surface of the rack 25. The outer surface of the rack 25 is provided with a fixing groove 205, the lamp strip 70 is a soft LED lamp strip fixed in the fixing groove 205.

The principle of the disclosure is as follows: In works, the rotary flying ball is started, the power supply 50 powers the motor 60 and the strip 70 through the main control board 40. The motor 60 works to drive the paddle 30 to rotate, the rotating direction of the paddle 30 is contrast with the bracket 20 so that the torsion generated by relative rotation between the bracket 20 and the paddle 30 counteracts each other and generates downward wind, thereby causing the lift of the rotary flying ball, the lamp strip 70 is illuminated to light. After the rotary flying ball is thrown out, it stably flies in the air according to the thrown angle, with the works of the external force, the rotary flying ball flies a distance towards the thrown direction, then because of the gyro effect produced by the rotation of the bracket, the flight angle of the rotary flying ball remains constant and the rotary flying ball continues to fly in the direction of that angle. That is to say, users can preset the throwing angle of the rotary flying ball, thereby obtaining different flight trajectories. In the flight process, the rotary flying ball will generate cool lighting effect.

The design focus of the disclosure is concerned: The rotary flying ball is designed as a ball shape and used the motor to drive the paddle to rotate; when the rotary flying ball is thrown out, it stably flies in the air at the thrown angle. Under the works of the external force thrown, the rotary flying ball flies a distance in the direction thrown, then because of the gyro effect produced by the rotation of the bracket and the paddle, the flight angle of the rotary flying ball remains constant and the rotary flying ball continues to fly in the direction of that angle. Users can preset the throwing angles of the rotary flying ball, thereby obtaining different flight trajectories, no remote control is required to control the flight trajectories. Users can throw the rotary flying ball according to the presetting angles to obtain the presetting flight trajectories, and the rotary flying ball can achieve to stably and instantly fly in the air. The rotary flying ball is simple in structure and easy to operate. At the same time, with the lamp strip, the rotary flying ball can produce a cool lighting effect.

The technical principles of the disclosure are described above in combination with specific embodiments. These descriptions are only intended to explain the principles of the disclosure, and cannot be interpreted in any way as limiting the protection scope of the disclosure. Based on the interpretation herein, those skilled in the art may associate of other specific embodiments of the disclosure without any creative labor, all of which will fall within the protection scope of the disclosure.

Claims

1. A rotary flying ball, comprising a housing, a bracket, a paddle, a main control board, a power supply, a motor, and a lamp strip; said housing is spherical, said housing is provided with an accommodation space therein and multiple holes communicated with said accommodation space thereon;said bracket is mounted in said accommodation space, said bracket provides a shaft, a central of said shaft coincides with a center of said housing;said paddle is located in said accommodating space and rotatably disposed on said shaft;said main control board, said power supply, said motor, and said lamp strip are mounted on said bracket; said power supply, said motor, and said lamp strip are electrically connected with said main control board, said motor drives said paddle to rotate;said bracket has a rack, both ends of said shaft are fixedly connected with an upper side and a bottom side of said housing, respectively; and both ends of said rack are sleeved at both ends of said shaft, respectively; said lamp strip is fixed on an outer surface of said rack.

2. The rotary flying ball according to claim 1, wherein said bracket includes a lower seat, a motor cover, an upper seat, and a pressure cover; said motor cover is fixed with said lower seat to enclose a first cavity; said power supply and said motor are arranged in said first cavity; said upper seat is fixed on said motor cover; said pressure cover is fixed with one end of said rack and said upper seat to enclose a second cavity, said main control board is mounted in said second cavity; said shaft passes said first cavity and said second cavity.

3. The rotary flying ball according to claim 2, wherein a periphery of said lower seat provides a plurality of said first rotating blades spaced around a periphery of said shaft, with hollow areas between adjacent said rotating blades.

4. The rotary flying ball according to claim 3, wherein said paddle provides a plurality of said second rotating blades along an upper and down direction of said housing, said second rotating blades and said first rotating blades are arranged obliquely, respectively, and inclined directions of the first rotating blades and those of the second rotating blades are opposite.

5. The rotary flying ball according to claim 4, wherein said second rotating blades are arranged in a curved shape along said periphery of said shaft, and said plurality of said second rotating blades are curved in the same direction.

6. The rotary flying ball according to claim 1, wherein an outer surface of said rack is provided with a fixing groove, said lamp strip is a soft LED lamp strip fixed in said fixing groove.

7. The rotary flying ball according to claim 1, wherein said shaft provides a drive gear, said paddle is fixedly sleeved with said drive gear, an output shaft of said motor is fixed with an active gear engaged with said drive gear.

8. The rotary flying ball according to claim 1, wherein said housing includes an upper cover and a lower cover, which are fastened and enclosed to form said accommodation space, said upper cover and said lower cover are hollowed out to form said holes communicated with said accommodation space.

9. The rotary flying ball according to claim 1, wherein said main control board provides a main control chip connected with an acceleration sensor feedback signal to said main control chip, said main control chip controls said motor to rotate.