Flying skateboard

Abstract

Disclosed is a flying skateboard which comprises a bearing part, power parts, a main control module and altitude induction modules. The bearing part comprises a left foot bearing area and a right foot bearing area which are connected, can rotate oppositely when pedaled with foot soles of a human body and can be located on the same plane or on different planes. The main control module comprises a gyroscope and used for controlling the power output of the power parts to keep the balance of the flying skateboard and make the flying skateboard to vertically move up and down or hover. The altitude induction modules are used for measuring the distances between the altitude induction modules and the ground to make the flying altitude of the flying skateboard within the altitude limit threshold value range.

Claims

1. A flying skateboard, comprising a bearing part, power parts, a main control module and altitude induction modules; wherein the bearing part comprises a left foot bearing area and a right foot bearing area configured for bearing a left foot and a right foot of a human body; the left foot bearing area and the right foot bearing area are connected with each other; and the left foot bearing area and the right foot bearing area are configured to rotate oppositely under a pressure generated by pedaling on the left foot bearing area and the right foot bearing area with foot soles of the human body, so that the left foot bearing area and the right foot bearing area are controlled to located on a same plane or different planes; the power parts are arranged on the periphery of the bearing part and configured for supplying power to the flying skateboard for movement in all directions; the main control module comprises a gyroscope; and the gyroscope is installed on the bearing part and is configured for controlling a power output of the power parts to keep balance of the flying skateboard and make the flying skateboard to move vertically up and down or hover; the altitude induction modules are installed on the bearing part, altitude limit threshold values are set in the altitude induction modules, and the altitude induction modules are configured for measuring the distances between the altitude induction modules and the ground; and the altitude induction modules work in cooperation with the power parts to keep the flight altitude of the flying skateboard within the altitude limit threshold value range.

2. The flying skateboard according to claim 1, wherein when the bearing part integrally inclines forwards, the power parts also incline forwards, and the flying skateboard moves forward; when the bearing part internally inclines backwards, the power parts also incline backwards, and the flying skateboard moves backward or brakes; when the bearing part integrally inclines leftwards, the power parts also incline leftwards, and the flying skateboard horizontally moves to the left; when the bearing part integrally inclines rightwards, the power parts also incline rightwards, and the flying skateboard horizontally moves to the right.

3. The flying skateboard according to claim 1, wherein when the left foot bearing area rotates backwards relative to the right foot bearing area, the power parts connected with the left foot bearing area also inclines backwards relative to the power parts connected with the right foot bearing area, and the flying skateboard turns left; when the left foot bearing area rotates forwards relative to the right foot bearing area, the power parts connected with the left foot bearing area also incline forwards relative to the power parts connected with the right foot bearing area, and the flying skateboard turns right; when the left foot bearing area and the right foot bearing area are located on the same plane, the power parts connected with the left foot bearing area and the power parts connected with the right foot bearing area are also located on the same plane, and the flying skateboard does not turn in a direction.

4. The flying skateboard according to claim 1, wherein each power parts comprises a plurality of power segments, and the plurality of power segments are all connected with the bearing part and arranged on the left foot bearing area and the right foot bearing area of the bearing part uniformly.

5. The flying skateboard according to claim 4, wherein each power segment comprises one or more power modules arranged in an array mode and each power module is covered with a cover plate, the cover plate is provided with air holes above the power module correspondingly, and airflow hoods are installed in the air holes of the cover plate correspondingly.

6. The flying skateboard according to claim 5, wherein the power modules are internal combustion engines or motors, duct engines, jet engines or rocket engines.

7. The flying skateboard according to claim 1, wherein sensors are installed on a surface of the left foot bearing area and a surface of the right foot bearing area correspondingly and configured for sensing motions of the left foot and the right foot of the human body and the pressure applied to the flying skateboard.

8. The flying skateboard according to claim 2, wherein each power part comprises a plurality of power segments, and the plurality of power segments are all connected with the bearing part and arranged on the left foot bearing area and the right foot bearing area of the bearing part uniformly.

9. The flying skateboard according to claim 2, wherein each power part comprises a plurality of power segments, and the plurality of power segments are all connected with the bearing part and arranged on the left foot bearing area and the right foot bearing area of the bearing part uniformly.

10. The flying skateboard according to claim 3, wherein each power part comprises a plurality of power segments, and the plurality of power segments are all connected with the bearing part and arranged on the left foot bearing area and the right foot bearing area of the bearing part uniformly.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a top view of the present invention;

(2) FIG. 2 is a stereo view of the present invention;

(3) FIG. 3 is a manned-state view of the present invention:

(4) FIG. 4 is an exploded view of power parts of the present invention:

(5) FIG. 5 is a turning-left state view of the present invention:

(6) FIG. 6 is a turning-right state view of the present invention;

(7) FIG. 7 is a module installation position view of the present invention; and

(8) FIG. 8 is an altitude limit induction schematic diagram of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

(9) A further description of the specific execution mode of the present invention is given with accompanying drawings as follows.

(10) FIG. 1 and FIG. 2 are views of the present invention. As is shown in FIG. 1 and FIG. 2, the flying skateboard of the present invention comprises a bearing part 1 and power parts 2.

(11) The bearing part 1 comprises two bearing areas (as is shown in FIG. 2), namely the left foot bearing area 3 and the right foot bearing area 4. When a human body stands on the bearing part 1 (as is shown in FIG. 3), the left foot bearing area 3 is used for bearing the left foot of the human body, and the right foot bearing area 4 is used for bearing the right foot of the human body. The left foot bearing area 3 and the right foot bearing area 4 are connected and can rotate oppositely when pedaled with the food soles of the human body so that the left foot bearing area 3 and the right foot bearing area 4 can be located on the same plane or located on different planes. The power parts 2 are arranged on the periphery of the bearing part 1 and used for supplying power to the flying skateboard for movement in all directions.

(12) The power parts 2 each comprise a plurality of power segments, and the plurality of power segments are all connected with the bearing part 1 and arranged on the left foot bearing area 3 and the right foot bearing area 4 of the bearing part 1 uniformly. As is shown in FIG. 1 and FIG. 2, four power segments are included, two of the four power segments are arranged on the left front portion and the left rear portion of the left foot bearing area 3, and the other two power segments are arranged on the right front portion and right rear portion of the right foot bearing area 4.

(13) FIG. 4 is the exploded view of the power parts of the present invention. As is shown in FIG. 4, each power segment comprises one or more power module 5 arranged in an array mode, and the power modules 5 are internal combustion engines or motors or duct engines or jet engines or rocket engines. Each power segment is covered with a cover plate 6, the cover plates 6 are provided with air holes above the power modules 5 correspondingly, and airflow hoods 7 are installed in the air holes of the cover plates correspondingly.

(14) The control mode of the movement direction of the flying skateboard of the present invention is as follows:

(15) 1. Advancing, retreating, braking and horizontal movement are controlled in a mechanical control mode simulating a ground skateboard through foot motions of an operator:

(16) When the bearing part 1 inclines forwards, the power parts 2 also incline forwards to generate forward acting force, and the flying skateboard advances:

(17) when the bearing part 1 inclines backwards, the power parts 2 also incline backwards to generate backward acting force, and the flying skateboard retreats or brakes:

(18) when the bearing part 1 inclines leftwards, the power parts 2 also incline leftwards to generate leftward acting force, and the flying skateboard horizontally moves leftwards;

(19) when the bearing part 1 inclines rightwards, the power parts 2 also incline rightwards to generate rightward acting force, and the flying skateboard horizontally moves rightwards.

(20) 2. Turning is controlled in a mechanical control mode through foot motions of the operator:

(21) As is shown in FIG. 5, when the left foot bearing area 3 rotates backwards relative to the right foot bearing area 4, the power part connected with the left foot bearing area 3 also inclines backwards relative to the power part connected with the right foot bearing area 4, so that turning-left acting force is generated, and the flying skateboard turns left:

(22) as is shown in FIG. 6, when the left foot bearing area 3 rotates forwards relative to the right foot bearing area 4, the power part connected with the left foot bearing area 3 also inclines forwards relative to the power part connected with the right foot bearing area 4, so that turning-right acting force is generated, and the flying skateboard turns right;

(23) when the left foot bearing area 3 and the right foot bearing area 4 are located on the same plane, the power part connected with the left foot bearing area 3 and the power part connected with the right foot bearing area 4 are also located on the same plane, so that no turning acting force is generated, and the flying skateboard does not turn.

(24) 3. Altitude control is achieved through an existing flying control mode and assisted with altitude limit control:

(25) Please see FIG. 7, a main control module 8 is installed between the left foot bearing area 3 and the right foot bearing area 4 in the embodiment. The main control module 8 adopts existing flying control, comprises a gyroscope and can control the power output of all the plurality of power segments, so that the balance of the flying skateboard is kept, and the flying skateboard is made to vertically move up and down or hover in the air.

(26) Please see FIG. 7, altitude induction modules 9 are installed at the junctions of the bearing part 1 and the power parts 2. Altitude limit threshold values are set in the altitude induction modules 9. As is shown in FIG. 8, the altitude induction modules 9 can measure the distances between the altitude induction modules 9 and the ground and give an alarm to the operator of the flying skateboard when the distances exceed the altitude limit threshold values, so that it is ensured that the flying skateboard is at the safe altitude.

(27) Selectively, sensors 10 (as is shown in FIG. 2) are installed on the surface of the left foot bearing area 3 and the surface of the right foot bearing area 4 correspondingly and used for sensing motions of the left foot and the right foot of the human body and the pressure applied to the surface of the bearing part 1 and sending the information to the main control module 8, and auxiliary control is achieved through the main control module 8.

(28) The foregoing description is only the preferred embodiment of the present invention, and the present invention is not limited to the description. It can be understood that other improvements and changes which are directly derived or thought out by those skilled in the field without deviating the spirit and conception of the present invention are all included in the protection scope of the present invention.