FLIGHT VEHICLE

Abstract

Recently, jobs involving transporting goods, tasks involving surveying a wide area, etc. using multicopters have increased, and it has become necessary for multicopters to fly for long periods of time, In the present invention, wings that are separate from the main body are provided all the way around or at individual locations around it to connect neighboring pairs of the multiple arms extending radially from it, in order to increase the multicopter’s lift and extend its flight time.

Claims

1. A flight vehicle that has a main body (1) at its center where the controller is mounted and motors (4) and propellers (3) at the tips of multiple arms (2) extending radially from the main body (1), and is characterized by having wings (11) that are separate from the aforementioned main body (1), are provided all the way around or at individual locations around it to connect all or some of the neighboring pairs of the aforementioned arms (2), and are attached at a constant distance between the main body (1) and propellers (3).

2. A flight vehicle as in claim 1 that is characterized by the following: the batteries (12) are mounted inside the aforementioned wings (11).

3. A flight vehicle as in claim 1 that is characterized by the following: the aforementioned wings (11) are tilted toward its direction of travel.

4. A flight vehicle as in claim 1 that is characterized by the following: the cross sections of the wings (11) include ellipses and polygons.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0009] FIG. [Drawing 1] Top view of a multicopter (with six propellers)

[0010] [FIG. Drawing 2] Vertical cross section of a multicopter (with six propellers)

[0011] [FIG. Drawing 3] Air flow when the multicopter is moving forward

[0012] [FIG. Drawing 4] Top view showing an example with the batteries mounted inside the wings (with six propellers)

[0013] [FIG. Drawing 5] Vertical cross section showing an example with the batteries mounted inside the wings (with six propellers)

[0014] [FIG. Drawing 6] Vertical cross section showing an example with the wings tilted toward the direction of travel

[0015] [FIG. Drawing 7] Air flow when the multicopter is moving forward with the wings tilted toward the direction of travel

[0016] [FIG. Drawing 8] Top view of a multicopter with four propellers

[0017] [FIG. Drawing 9] Vertical cross section of a multicopter with four propellers

[0018] [FIG. Drawing 10] Example with polygonal wings

[0019] [FIG. Drawing 11] Example with wings placed only between two arbitrary pairs of arms at the front and back relative to the direction of travel

[0020] [FIG. Drawing 12] Example of the detailed cross section of a wing

[0021] [FIG. Drawing 13] Example of the detailed cross section of a wing tilted toward the direction of travel

[0022] [FIG. Drawing 14] Example of the detailed cross section of a polygonal wing

MODES FOR IMPLEMENTING THE INVENTION

[0023] FIGS. Drawings 1 and 2 show an example implementation with a multicopter with six arms, six propellers, and six motors. At the center of the multicopter is its main body 1 where the controller is mounted, and extending radially from that are the arms 2. Each of the arms 2 has a propeller 3, motor 4, and ESC 5 attached at its tip and an arm folding hinge 14 in the middle of it. The hinges enable the arms 2 to be folded so that the multicopter can be transported more compactly.

[0024] Attached between the multicopter main body 1 and arm folding hinges 14 are wings 11, which are separate from the multicopter main body 1.

[0025] The wings 11 are fixed to the arms 2.

[0026] The wings 11 are provided for the radial arms 2 all the way around, or for multiple neighboring pairs of them. FIG. Drawing 3 shows the present invention actually in use on a multicopter.

[0027] It shows the air flow when the multicopter is moving forward, and that because the propellers are rotating on the outer side of the wings, the air flow there is fast, and the resulting slipstream pulls in the air flow on the inner side so that it does not separate off.

[0028] The angle of attack of the wings 11 increases when the multicopter tilts forward to move forward, and if it continues to move forward, air flows in around it. However, on the higher side of the multicopter main body 1, the rotation of propeller 3A on the outer side of wing 11A creates a slipstream that speeds up the air flow so that it does not separate off even if the angle of attack is large. The air flowing through space S1 between the multicopter main body 1 and wing 11A is moving slower than that flowing through the outer space S2 between wing 11A and propeller 3A. The difference between the flow speeds generates upward lift. Similarly, on the opposite, lower side of the multicopter main body 1, propeller 33 is rotating on the outer .Math.side of wing 11B, and the slipstream created by it is flowing through space S2. Here, the air flowing through space S1 on the inner side of wing 11B is also moving slower than that on the outer side, and would ordinarily separate off due to the large angle of attack. However, close to wing 11B on its outer side (S2 there there is propeller 3B, and the slipstream created by it pulls in the air flow so that it does not separate off. The difference between the flow speeds generates downward lift. In this way, the propeller slipstream lifts generated at the front and back offset each other, the ones generated on the left and right do likewise, and lift is generated by the influx of air due to the multicopter’s forward movement.

[0029] Furthermore, because the air flow does not separate off from the wings 11, the multicopter can fly with less resistance. Using this lift to offset the multicopter’s weight makes it lighter. This in turn enables it to fly for a longer time by reducing the resistance to it, the load on its motors, and the electricity it consumes. Similarly, when the multicopter is hovering, since the propellers 3 are on the outer side (S2 side) of the wings 11, lifts are constantly generated on the outer side (S2 side). However, the lifts generated at the front and back offset each other and the ones generated on the left and right do likewise. As a result, the multicopter can be kept stationary.

[0030] This enables the flight time of the multicopter to be extended by approximately 20%. The multicopteris flown with the wings 11 at a large angle of attack but when it is flying slowly the resulting resistance is small and not much of a problem. However the flight speed increases, the resistance will as well. To reduce the resistance therefore, the wings can be tilted toward the multicopter’s direction of travel, to an extend that will not affect its hovering capability.

[0031] FIGS. Drawings 4 and 5 show an example of mounting the batteries using the empty spaces in the wings. FIGS. Drawings 6 and 7 show an example of reducing the wings’ angle of attack so that they generate less resistance. Reducing the angle of attack will enable the speed to be increased further. The angle can also be made automatically variable.

[0032] FIGS. Drawings 8 and 9 show an example application when there are four propellers.

[0033] FIG. Drawing 10 shows an example application where the wings have a polygon cross section that can easily accommodate the batteries. Sufficient lift can be generated even if they are polygonal. Furthermore, besides the cross sections that are already in practical use as airfoils, those of the wings 11 also include approximated ones such as ellipses and polygons.

[0034] FIG. Drawing 11 shows an example in which the wings 11 are placed between two arbitrary pairs of arms. The effect is sufficient even if the wings 11 are not placed between all the arms, but only an arbitrary pair at the front and back relative to the direction of travel.

[0035] FIG. Drawing 12 shows an example cross section of a wing.

[0036] FIG. Drawing 13 shows an example cross section of a wing that has been tilted forward.

[0037] FIG. Drawing 14 shows an example cross section of a polygonal wing.

TABLE-US-00001 1 Multicopter main body 2 Arm 3 Propeller 3A Propeller on higher side 3B Propeller on lower side 4 Motor 5 ESC (Motor controller) 6 Main controller 7 Secondary controller 8 GPS antenna 9 Receiver 10 Video transmitter 11 Wing 11A Wing on higher side 11B Wing on lower side 12 Battery 13 Leg 14 Arm folding hinge 15 Camera, measuring device, transportation case, etc. 16 Muiticopter’s direction of travel 17 Air flow around multicopter 18 Wing tilted forward S1: Space between main body and wing S2: Space between wing and propeller