KR101953892B1 - Vertical takeoff and landing aircraft with distributed propulsion system and control method of thereof - Google Patents

Abstract

The vertical take-off and landing dispersion propulsion type aircraft according to an embodiment of the present invention includes a body portion having a pitching angle to the ground changed according to a flight mode, an upper wing portion and a lower wing portion connected to the body portion in the form of a fixed wing, And a plurality of upper propellers and a plurality of lower propellers respectively connected to the lower wing portion and the lower wing portion.
The upper propeller and the lower propeller provide lift in the vertical take-off mode and provide thrust in the forward flight mode.

Description

TECHNICAL FIELD [0001] The present invention relates to a vertical take-off and landing distributed propulsion type aircraft and a control method thereof,

The present invention relates to a vertical landing and landing dispersion propulsion aircraft and a control method thereof.

If the aircraft has a vertical takeoff and landing function, it can take off in place without a glide and land directly at the point where it stops in the air, which is a great advantage in operation. An aircraft capable of vertical landing and landing, for example, a helicopter, is mainly driven by an internal combustion engine and an environmentally friendly propulsion device (electric motor and battery or fuel cell) to rotate a rotor or a propeller parallel to the ground, ) To get the desired altitude and then make a forward flight.

However, such a vertical takeoff and landing aircraft must generate thrust necessary for flight only by rotating the rotor, and if the rotation speed of the rotor increases, the performance decreases (lift reduction and rapid drag increase) Which is disadvantageous to high-speed driving. Therefore, most of the aircraft requiring high speed and long haul are equipped with fixed wing type wing (main wing) to gain lift and obtain thrust using rotor or propeller.

Recently, a tilt-rotor type aircraft has been actively studied, which has the advantages of vertical take-off and landing and strong thrust. The tilt rotor aircraft takes a vertical takeoff by rotating the rotor parallel to the ground, then pivoting the rotation surface of the rotor 90 degrees to get thrust and perform forward flight. However, the control logic for correct posture must be very sophisticated in the course of performing the posture change.

Korean Patent No. 10-0822366 (Registered on April 4, 2008)

The tilt-rotor type aircraft described above is difficult to experiment, manufacture, and control due to the complexity of the mechanical device for performing pivoting with respect to the rotor body.

In addition, when an unexpected situation occurs, such as when a part of the rotor stops rotating due to a problem in the power source during the flight, it is impossible to control the attitude of the aircraft, and thus there is a great risk of an air accident.

Also, since the tilt-rotor type aircraft uses a rotor with a large diameter to obtain sufficient thrust, only a part of the air stream accelerated by the blade of the rotor is utilized to increase the lift of the wing. The ratio (L / D ratio) can not be increased.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems and it is an object of the present invention to provide an air conditioner that can be easily controlled by using an upper wing disposed in a two-layered configuration, a plurality of upper propellers disposed in a lower wing, And an object of the present invention is to provide a vertical take-off and landing dispersive propulsion type aircraft with a high stability ratio and a large L / D ratio and a control method thereof. However, these problems are illustrative and do not limit the scope of the present invention.

According to an embodiment of the present invention, there is provided a vertical landing and landing dispersion propulsion aircraft comprising: a body portion having a pitching angle with respect to a ground; An upper wing portion and a lower wing portion connected to the body portion in a fixed wing shape; A plurality of upper propellers and a plurality of lower propellers connected to the upper wing portion and the lower wing portion, respectively, wherein the upper propeller and the lower propeller provide lift in the vertical take-off mode and provide thrust in the forward flight mode .

According to one embodiment, the upper propeller may be disposed on the left and right sides of the upper wing portion respectively, and the lower propeller may be disposed on the left and right sides of the upper wing portion, respectively.

According to one embodiment, when the flight mode is changed from the vertical take-off mode to the forward flight mode, the rotation speed per minute of the specific upper propeller among the plurality of upper propellers is set to a speed corresponding to the minute speed of the lower propeller corresponding to the position of the specific upper propeller, May be greater than the number of revolutions.

According to one embodiment, the upper wing and the lower wing may include a steering surface such as a flapper that adjusts lift during flight.

The vertical take-off and landing dispersion propulsion type aircraft according to an embodiment of the present invention further includes a battery feeder for supplying power for operating a propulsion engine to the inside of the body, and a battery feeder for shifting the position of the battery when the flight mode is changed .

According to an embodiment, when the flight mode changes from the vertical take-off mode to the forward flight mode, the battery transfer unit may move the battery toward the front of the body. At this time, it is possible to change the posture of the aircraft through the movement of the battery and the generation of the pitching moment due to the difference in rotation speed per minute between the propeller located at the upper wing portion and the lower wing portion.

According to one embodiment, the lower wing portion may be disposed in front of the body portion with respect to the upper wing portion.

According to an embodiment of the present invention, the upper propeller disposed at the outermost side of the upper wing portion of the plurality of upper propellers has a longer blade length than the remaining upper propellers and is disposed at the outermost side of the lower wing portion of the plurality of lower propellers The lower propeller may have a longer blade length than the lower propeller.

Increasing the number of rotations of a number of propellers located inside the upper wing and lower wing in a forward flight accelerates the velocity of the wake past these rotating surfaces, thereby increasing the flow velocity above and below the wing. As a result, the lift generated by the wing portion increases, thereby enabling high-speed and long-distance flying. This is an advantage of using the dispersing thrust device, and a plurality of propulsion devices are attached to the wing portion, so that even if some of them are not operated, the remaining thrust device can be used to safely move to a desired point, thereby ensuring stability of the aircraft.

The control method of the vertical take-off and landing propulsion type aircraft according to an embodiment of the present invention includes a take-off step, a transfer step, and a forward flight step, which are sequentially performed, and the take-off step is connected to the upper wing portion and the lower wing portion And rotating the plurality of upper propellers and the lower propellers by varying the number of revolutions per minute of the plurality of upper propellers and lower propellers to change the pitch angle with respect to the ground of the body portion.

According to an embodiment, the transition step and the forward flight step may further include adjusting an angle of the steering surface included in the upper wing portion and the lower wing portion.

According to an embodiment of the present invention, the transition step may further include moving a battery disposed inside the body part toward a front side of the body part.

According to one embodiment, the forward flight step may include reducing the number of revolutions per minute of the upper and lower propellers disposed at the outermost of the upper propeller and the lower propeller, and rotating the upper propeller and the lower propeller, And increasing the number.

According to an embodiment, the step of advancing and advancing may further include moving a battery disposed inside the body part toward a backward direction of the body part.

Other aspects, features, and advantages will become apparent from the following drawings, claims, and detailed description of the invention.

The aircraft according to an embodiment of the present invention may implement the vertical takeoff and landing mode and the forward flight mode by adjusting the number of revolutions per minute of the propeller connected to the wing having the two-layer structure. Therefore, there is no need for a device for tilting the wing portion or the propeller, so that the mechanical structure is simple, and manufacturing, maintenance, and control are relatively simple.

In addition, since the aircraft according to the embodiment of the present invention uses a plurality of propellers for distributed propulsion, even if a part of the propulsion device in flight is broken, the posture of the aircraft can be controlled through another propulsion device, Is reduced.

Also, the aircraft according to an embodiment of the present invention may increase the L / D ratio because a plurality of propellers having a small diameter are connected to the wing portion to increase lift through the wake generated by the propeller .

According to the control method of an aircraft according to an embodiment of the present invention, the movement of the battery using the two-layered propeller, the auxiliary blade or the battery transfer unit can be controlled to perform the (vertical) takeoff step, the transition step, have. In particular, since the pitching moment is controlled through various control methods at the transition stage, stability in operation is increased. Of course, the scope of the present invention is not limited by these effects.

1 is a perspective view schematically illustrating a vertical landing and landing distribution propulsion aircraft according to an embodiment of the present invention.
FIGS. 2A to 2C are schematic views illustrating a flight mode of a vertical landing and landing distribution propulsion type aircraft according to an exemplary embodiment of the present invention.
3 is a side view of a vertical landing and landing dispersal propulsion aircraft in accordance with one embodiment.
4 is a side view of a vertical takeoff and landing dispersion propulsion aircraft according to another embodiment.
5 is a side view of a vertical takeoff and landing dispersion propulsion aircraft according to another embodiment of the present invention.
6 is a front view of a vertical takeoff and landing distribution propulsion aircraft according to an embodiment of the present invention.
FIG. 7 is a flowchart illustrating a control method of a vertical landing and landing dispersion propulsion type airplane according to an embodiment of the present invention,
8A to 8E are diagrams showing the state of an aircraft controlled according to the control method according to each step.

The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in the detailed description. The effects and features of the present invention and methods of achieving them will be apparent with reference to the embodiments described in detail below with reference to the drawings. However, the present invention is not limited to the embodiments described below, but may be implemented in various forms.

In the following embodiments, the terms first, second, etc. are used for the purpose of distinguishing one element from another element, rather than limiting.

In the following examples, the singular forms "a", "an" and "the" include plural referents unless the context clearly dictates otherwise.

In the following embodiments, terms such as inclusive or possessive are intended to mean that a feature, or element, described in the specification is present, and does not preclude the possibility that one or more other features or elements may be added.

If certain embodiments are otherwise feasible, the specific steps may be performed differently from the described order. For example, two successively described steps may be performed substantially concurrently, or may be performed in a reverse order to that described.

In the drawings, components may be exaggerated or reduced in size for convenience of explanation. For example, the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of explanation, and thus the present invention is not necessarily limited to those shown in the drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, wherein like reference numerals refer to like or corresponding components throughout the drawings, and a duplicate description thereof will be omitted .

1 is a perspective view schematically illustrating a vertical landing and landing distribution propulsion aircraft according to an embodiment of the present invention. Hereinafter, the term 'vertical takeoff and landing dispersion propulsion aircraft' shall be abbreviated as 'aircraft'.

Hereinafter, the direction of travel of the aircraft at forward flight or cruise is defined as x direction, the direction opposite to gravity is defined as z direction, the direction perpendicular to x direction and z direction and the left direction of aircraft is defined as y direction .

Hereinafter, expressions such as 'up', 'up', 'down', 'under' and the like may indicate relative positions in the z direction when the aircraft is in forward flight.

Hereinafter, expressions such as 'front', 'rear', and 'rear' may indicate relative positions relative to the x direction when the aircraft is in flight.

Hereinafter, the expressions such as 'left' and 'right' may indicate relative positions when the direction in which the aircraft is moving forward is the forward direction.

The vertical take-off and landing dispersing propulsion type aircraft according to an embodiment includes a body 100 having a pitch angle with respect to the ground according to a flight mode, an upper wing 100 connected to the body 100 in a fixed wing shape A plurality of upper propellers 210 and a plurality of lower propellers 310 connected to the upper wing portion 200 and the lower wing portion 300, the upper wing portion 200 and the lower wing portion 300, respectively.

Referring to FIG. 1, an upper wing portion 200 and a lower wing portion 300 are disposed above and below the body portion 100, respectively. In other words, the aircraft has a wing in the form of two layers. The upper wing portion 200 and the lower wing portion 300 may be disposed outside the body 100 as shown in FIG. 1, but may be disposed as protruding from the body 100. In any form, the upper wing portion 200 and the lower wing portion 300 serve as a main wing of an aircraft having a fixed wing shape and provide a lift to an aircraft in a forward flight.

The lengths, aspect ratios and airfoil shapes of the upper and lower wings 200 and 300 may be the same. In this case, the center of gravity when the aircraft takes off and land vertically is not shifted to one side, thereby increasing the stability and reducing the manufacturing cost of the aircraft. On the other hand, the upper wing portion 200 and the lower wing portion 300 may be arranged to have different angles of attack. For example, the angle of attack of the upper wing portion 200 may be greater than the angle of attack of the lower wing portion 300, so as to provide a larger lift.

A plurality of upper propellers 210 are connected to the upper wing portion 200. A blade of the upper propeller 210 may rotate to provide a lift and thrust to the aircraft. The central portion of the upper propeller 210 may be disposed at a leading edge of the upper wing portion 200, but the present invention is not limited thereto.

The number, position, size, and the like of the upper propeller 210 can be appropriately selected according to the length of the upper wing portion 200, desired aerodynamic characteristics, and the like. However, it is preferable that they are designed and arranged such that interference due to a stream generated at the rear of each upper propeller 210 does not occur. On the other hand, the size, shape, and rotation speed of each upper propeller 210 may be different from each other. Although the upper propeller 210 has a different shape, it is preferable that the upper propeller 210 is configured symmetrically with respect to the center of the upper wing portion 200, that is, the x axis in FIG.

The plurality of upper propellers 210 generate the propulsive force required for the operation of the aircraft by distributed propulsion. According to one embodiment, two or more upper propellers 210 may be disposed on the left and right sides of the upper wing portion 200, respectively. In FIG. 1, five upper propellers 210 are arranged symmetrically on the left and right sides, but the present invention is not limited thereto. In this case, the remaining upper propellers 211L, 212L, 214L, and 215L are still driven even in an unexpected situation such as when a part of one of the upper propellers (e.g., the left propeller 213L) And the risk of an air accident is reduced.

Meanwhile, a plurality of lower propellers 310 are connected to the lower wing portion 300. The lower propeller 310 also has similar features to the upper propeller 210, so that detailed description is omitted.

The upper propeller 210 and the lower propeller 310 provide lift to the aircraft in the vertical take-off mode and provide thrust in the forward flight mode, and hereafter the mechanism is described.

FIGS. 2A to 2C are schematic views illustrating a flight mode of a vertical landing and landing distribution propulsion type aircraft according to an exemplary embodiment of the present invention.

The flight mode of the aircraft has a vertical take-off and landing (VTOL) mode, which is a first mode M1, and an advanced flight mode, which is a second mode M2. 2A shows a state in which the aircraft is in the vertical take-off mode. In the vertical take-off mode, the front end (nose) 110 of the body part 100 faces the opposite direction of gravity (z direction), i.e., toward the sky. The tail portion 120 behind the body portion 100 may include a flat portion so that the aircraft can maintain a 'line' condition on the floor. That is, the aircraft according to an embodiment of the present invention can borrow a tail-sitter method in which the tail portion 120 touches the ground before taking-off and landing. On the other hand, the tail 120 may have a shape to generate a stable low velocity flow field during forward flight to provide additional thrust.

In the vertical take-off and landing mode, the upper propeller 210 and the lower propeller 310 rotate to provide lift to the aircraft. At this time, the direction of rotation of the upper propeller 210 and the lower propeller 310 may be reversed. For example, when the blade 310B of the lower propeller 310 rotates clockwise, the blade 210B of the upper propeller 210 disposed at the corresponding position can rotate in a counterclockwise direction.

In this case, the magnitude of the lift L _u generated by the plurality of upper propellers 210 in the vertical take-off and landing mode may be the same as the magnitude of the lift L _l generated by the plurality of lower propellers 310. That is, the revolutions per minute (RPM) of the upper propeller 210 and the lower propeller 310 disposed at the corresponding positions above and below may be the same. As a result, the aircraft can be vertically landed and landed and hovered.

FIG. 2B shows the state of the aircraft at the transition from the vertical take-off mode M1 to the forward flight mode M2. According to one embodiment, when the flight mode changes from the vertical takeoff and landing mode to the forward flight mode, the revolutions per minute of a specific upper propeller among the plurality of upper propellers is greater than the revolutions per minute of the lower propeller corresponding to the position of the specific upper propeller . 1, the upper propeller 211L disposed at the left end of the upper wing portion 200 and the lower propeller 311L disposed at the left end of the lower wing portion 300 correspond to each other in position. In other words, in the transition state, the revolutions per minute of the left upper propeller 211L may be larger than the revolutions per minute of the left lower propeller 311L. Of course, the remaining propellers 212L to 215L, 312L to 315L on the left and the propellers 211R to 215R, 311R to 315R disposed on the right side can operate similarly.

The number of revolutions per minute of the upper propeller 210 is greater than the number of revolutions per minute of the lower propeller 310 so that the magnitude of the lift L _u generated by the upper propeller 210 is proportional to the lift generated by the lower propeller 310 L ₁ ). Therefore, a pitching moment acts to lower the nose of the body part 100, so that the front end 110 gradually faces the x direction. That is, the pitch angle (? _P ) with respect to the ground surface of the body part 100 is changed.

2C shows the second mode M2 of the aircraft, i.e., the forward flight mode. In the forward flight mode, the front end 110 of the body part 100 faces the x direction, and the pitch angle with respect to the ground surface of the body part 100 becomes close to 0 degrees. At this time, the upper propeller 210 and the lower propeller 310 rotate to provide thrusts T _u and T _l , respectively, and the upper wing portion 200 and the lower wing portion 300 respectively generate lift forces L _u and L _l , .

On the other hand, the air passing through the lower propeller 310 at the time of forward flight passes through the lower wing portion 300 with a wake accelerated than the peripheral speed. At this point, the wake passes below and above the wing, where the accelerated wake increases the relative pressure differential of the wing, which in turn results in an increase in lift, thereby resulting in an additional lift (L _p )

At this time, when the lower wing 300 is disposed at a position where the wake S by the lower propeller 310 has the maximum axial velocity, the size of the additional lift L _p can be maximized have. When the lower propeller 310 is reduced in size to increase the number of lower propellers 310 connected to the lower wing 300, the flow passing through the lower wing 300 is accelerated by the wake generated by the lower propeller 310, A larger lift is generated in the lower wing portion 300. This principle is similarly applied to the upper propeller 210 and the upper wing portion 200.

The aircraft according to an embodiment of the present invention may implement the vertical takeoff and landing mode and the forward flight mode by controlling the number of revolutions per minute of the propellers 210 and 310 connected to the wings 200 and 300 having a two-layer structure. Therefore, there is no need for a device for tilting the wing parts 200, 300 or the propellers 210, 310, so that the mechanical structure is simple and the manufacturing, maintenance, and control are relatively simple.

Also, since the aircraft according to the embodiment of the present invention can obtain additional lift by the wake, it is possible to generate a similar lift with a shorter chord length than a conventional aircraft having no two-story wing. Therefore, the weight of the upper wing portion 200 and the lower wing portion 300 can be reduced, and the lift force can be further increased. At this time, as the number of the upper propeller 210 and the lower propeller 310 is increased, the drag increases but the increase in lift is larger, so the overall drop ratio L / D can be increased.

Hereinafter, a mechanism for controlling the posture of the aircraft in the transition of the forward flight mode in the vertical takeoff and landing mode is described.

3 is a side view of a vertical landing and landing dispersal propulsion aircraft in accordance with one embodiment.

According to one embodiment, the upper wing portion 200 and the lower wing portion 300 may include a steering surface 220, 320 for controlling lift during flight.

Referring to FIG. 3, a flaperon-shaped steering surface 220, 320 disposed at a trailing edge of the upper wing portion 200 and the lower wing portion 300 and capable of controlling the magnitude of the lift force, . As the angle between the flaperon and the chord of the wing changes, the lift also changes. Therefore, the attitude of the aircraft can be controlled by adjusting the angles of the steering surfaces 220 and 320 of the upper wing portion 200 and the lower wing portion 300.

For example, when the transition from the vertical take-off mode to the forward flight mode starts, if the auxiliary wing 220 of the upper wing portion 200 is rotated downward, lift of the upper wing portion 200 becomes larger. Conversely, when the auxiliary wing 320 of the lower wing portion 300 is rotated upward, the lift force of the lower wing portion 300 becomes smaller. Accordingly, the movement of the control surfaces 220 and 320 can be controlled to apply a pitching moment to the body portion 100, and the posture in the transition phase can be controlled.

3, the auxiliary wing may be disposed in front of the wing portions 200 and 300, or may have a split configuration in which a part of the lower surface of the wing portion is divided and bent downward, and a part of the lower surface of the wing portion is slid backward And a Fowler-type that comes out of the body.

4 is a side view of a vertical takeoff and landing dispersion propulsion aircraft according to another embodiment. 4, the lower wing 300 and the lower propeller 310 are not shown for the sake of convenience of describing the battery B and the battery transferring unit 400 described later.

The vertical landing and landing dispersion propulsion aircraft according to an embodiment may further include a battery transfer unit 400 disposed inside the body part 100 and moving the battery B when the flight mode is changed. At this time, when the flying mode is changed from the vertical take-off mode to the forward flight mode, the battery transfer unit 400 can move the battery B toward the front side of the body 100.

The aircraft includes a control unit for electrically controlling the motion of the upper propeller 210, the lower propeller 310, and the like, and a battery B for providing electrical energy. However, the total weight of the battery (B) used in the unmanned aerial vehicle driven by electricity alone is heavy to occupy about 40% or more of the maximum takeoff weight (MTOW) of the aircraft. In this case, it is preferable to keep the center of gravity of the aircraft downward in order to ensure stability when the aircraft is taken off and landed and stored on the ground. Thus, when the battery B is positioned at the rear side of the body part 100 It is preferable to be placed on the lower side as a standard.

Even when the flight mode of the aircraft is shifting, when the battery B is placed on the rear side of the body 100, most of the weight of the battery B is lowered and the rotation speed of the upper propeller 210 and the lower propeller 310 It is difficult to adjust the pitch angle of the body portion 100 only by the use of the above-

Referring to FIG. 4, the battery B is moved to the front side of the body part 100 by the battery transfer part 400 in the transition step. When the battery B is moved forward in the transition phase, the pitching moment can be increased and the pitch angle of the body portion 100 can be easily adjusted.

The battery transfer unit 400 includes a holder 410 on which the battery B is placed, a sliding unit 420 that provides a path through which the holder 410 can move in the forward / backward direction, The battery feeder 400 may not have a separate power supplier 430. The battery charger 430 may be a battery charger. At this time, the holder 410 may receive power from the battery B and move on the sliding part 420 to move the battery B.

The structure of the battery transferring part 400 is not limited thereto, and various modifications are possible as long as the structure allows the battery B to move relative to the body part 100. The battery conveyance unit 400 and the battery B are preferably disposed on the center axis of the aircraft so that the center of gravity of the aircraft is not offset to the left or right.

I) adjustment of the revolutions per minute of the upper propeller 210 and the lower propeller 310, ii) angle adjustment of the auxiliary vanes 220 and 320, and iii) pitching The moment can be adjusted, thereby adjusting the pitch angle of the body part 100 and transferring the flight mode. At this time, the controller for controlling the movement of the upper propeller 210, the lower propeller 310, the auxiliary vanes 220 and 320, and the battery conveyance unit 400 can use all of the above three methods at the same time, Mode can be transferred.

5 is a side view of a vertical takeoff and landing dispersion propulsion aircraft according to another embodiment of the present invention.

According to one embodiment, the lower wing portion 300 may be disposed in front of the body portion 100 rather than the upper wing portion 200.

The pitching moment can be adjusted by changing the drag acting on the upper wing portion 200 and the lower wing portion 300 through the auxiliary wings 220 and 320 during the forward flight, 300 and the upper wing portion 200 are arranged back and forth so that the pitching moment can be adjusted by giving a difference in lift. For example, when it is desired to transition from the forward flight mode M2 to the vertical takeoff and landing mode M1, the rotation speed of the lower propeller 310 and the upper propeller 210 may be adjusted or the angle of the control surfaces 220 and 320 may be adjusted The lift L ₁ acting on the lower wing 300 can be made larger than the lift L _u acting on the upper wing 200. Accordingly, the pitching moment can be applied in the direction of lifting the cardinal number. In this case, the pitching moment can be adjusted more easily than in the case of using the drag force.

6 is a front view of a vertical takeoff and landing distribution propulsion aircraft according to an embodiment of the present invention.

The upper propellers 211L and 211R disposed on the outermost side of the upper wing portion 200 of the plurality of upper propellers 210 are made of a blade than the remaining upper propellers 212L to 215L and 212R to 215R, And the lower propellers 311L and 311R disposed on the outermost side of the lower wing portion 300 among the plurality of lower propellers 310 are blades than the remaining lower propellers 312L to 315L and 312R to 315R, May be long. In the following description, the lower propeller 310 is used as a reference but the upper propeller 210 has a similar logic.

The lower propeller 310 of the present invention provides lift in the vertical takeoff and landing mode and thrust in the forward flight mode. The greater the diameter of the lower propeller 310, the better the lift efficiency at the time of vertical takeoff and landing. However, It is not possible to obtain a powered lift due to the load. That is, the efficiency of the lower propeller 310 in the vertical takeoff and landing mode and the efficiency in the forward flight mode are in a trade-off.

In one embodiment of the present invention, a lower propeller having two diameters is used. 6, the diameter of the blades of the lower propellers 311L and 311R disposed on the outer side of the lower blade portion 300 may be greater than the diameter of the remaining lower propellers 312L to 315L and 312R to 315R .

At this time, during take-off and landing, the lower propellers 311L and 311R having large diameters are mainly used to increase the lift efficiency, while the lower propellers 312L to 315L and 312R to 315R having small diameters are used for forward flight, So that each advantage can be utilized.

On the other hand, the rotational directions of the lower propeller 310 disposed on the left and right sides may be reversed. When the lower propellers 312L to 315L arranged on the right side are rotated counterclockwise with respect to the left side of the body part 100 as shown in FIG. 6, the right side of the body part 100, The arranged lower propellers 312R to 315R can rotate clockwise. As a result, the moment generated by the rotation can be canceled.

In the case of the upper propeller 210, the same structure as that of the lower propeller 310 can be applied, so detailed description will be omitted. However, the direction of rotation of the upper propeller 210 and the lower propeller 310 may be reversed. On the other hand, the wake generated by the lower propellers 311L and 311R disposed on the outer side of the lower wing portion 300 is contracted as it passes through the rotation surface, so that turbulence can not be provided to the upper wing portion 200 even during forward flight.

Hereinafter, a control method of a vertical landing and landing distribution propulsion type aircraft according to an embodiment of the present invention will be described.

FIG. 7 is a flowchart illustrating a control method of a vertical landing and landing dispersal propulsion type aircraft according to an embodiment of the present invention. FIGS. 8A to 8E are diagrams illustrating states of an aircraft controlled according to the control method according to each step.

Referring to FIG. 7, the control method of the vertical landing and landing distribution propulsion type aircraft includes a take-off step (S10), a transition step (S20), and a forward flight step (S30).

8A shows the take-off step (S10). In the take-off step S10, a step S11 of rotating the upper propeller 210 and the lower propeller 310 of the aircraft whose front end of the body part 100 faces the z direction is performed. At this time, the upper propeller 210 and the lower propeller 310 provide lift to take off the aircraft.

5, when the lower wing 300 and the lower propeller 310 are positioned in front of the upper wing 200 and the upper propeller 210 in the take-off step S10, The ground effect is greater than that of the lower propeller 310 because the lower propeller 210 is closer to the ground G. [ Therefore, in this case, the controller can control the revolutions per minute of the upper propeller 210 and the lower propeller 310 in the direction to cancel the difference in the ground effect. 6, 211L, 211R, 311L, and 311R, which are disposed on the outermost side of the plurality of upper propellers 210 and lower propellers 310 and have a larger blade diameter, .

On the other hand, when the take-off is started, the battery B may be arranged at the rear of the body part 100, that is, at the bottom in FIG. 8A, in order to prevent a turnover phenomenon caused by wind or the like and increase the stability of the aircraft. However, after take-off, the battery B can be moved to the front side of the body part 100, that is, upward in FIG. 8A.

FIG. 8B shows a transition step S20. Transition step S20 may be performed after reaching the height (h _g ) at which the stability of the aircraft is secured due to the absence of ground effect. The height (h _g), but can be about 5m, we may vary depending on the size of the aircraft. In the transition step S20, a pitching moment is applied to the aircraft to change the pitch angle of the body 100 with respect to the ground.

At this time, the transition step S20 may include a step S21 of controlling the revolutions per minute of the upper propeller 210 and the lower propeller 310. Particularly, the control unit controls the rotation speed of the upper propeller 210 to be greater than the rotation speed per minute of the lower propeller 310 to apply a pitching moment to the aircraft.

The transition step S20 may further include a step S22 of adjusting the angles of the steering surfaces 220 and 320 included in the upper wing portion 200 and the lower wing portion 300. 8B, during the rotation of the body 100, the steering surface 220 included in the upper wing portion 200 faces downward to generate a larger lift, and the steering surface 220 included in the lower wing portion 300 320 may be directed upwards to generate a smaller lift. The control unit may control the movement of the control surfaces 220 and 320 to finely control the pitching moment.

The transition step S20 may further include a step S23 of moving the battery B disposed inside the body part 100 toward the front side of the body part 100. [ At this time, the battery B can move in the front direction of the body from the take-off step S10 to the transition stage, and at the altitude where there is no ground effect, the battery B can be moved to the center of the upper wing portion 200 and the lower wing portion 300 Can be located. At this time, the center of gravity of the entire battery transfer part 400 and the battery B, which move the battery B, can move to the trailing edge of the upper wing part 200. As the battery B moves, fine adjustment of the pitching moment is also possible.

That is, the transition step of the control method of the aircraft includes i) a step of controlling the rotation speed of the upper propeller 210 and the lower propeller 310 per minute, ii) an angle adjustment step of the control surfaces 220 and 320, iii) Moving in the forward direction of the unit 100, and each step may be performed selectively or concurrently. At this time, the control unit can control the upper propeller 210, the lower propeller 310, the auxiliary vanes 220 and 320, and the battery conveyance unit 400 so that the flight mode of the aircraft can be stably transferred.

8C shows the forward flight phase. In the forward flight phase, upper propeller 210 and lower propeller 310 provide thrust (T _u , T ₁ ) to the aircraft, respectively.

According to one embodiment, the forward flight phase is performed by the upper propeller 210 and the outermost propeller (FIG. 6, 211R, 211L) and the lower propeller (FIG. 6, 311R, 311L) (Fig. 6, 212L to 215L, 212R to 215R) and the lower propeller (Figs. 6, 312L to 315L, 312R to 315R) disposed in the lower portion of the upper propeller . At this time, the length of the upper propeller and the lower propeller can be greater than that of the remaining upper propeller and lower propeller.

Referring back to FIG. 6, as described above, in the vertical landing and landing phase, the control unit can provide lift by increasing the revolutions per minute of the lower propellers 311L and 311R disposed outside and having large diameters. After the transition, the control unit may control the RPM of the lower propellers 311L and 311R to be smaller than the revolutions per minute in the vertical takeoff and landing stage. On the other hand, the control unit can control the revolutions per minute of the lower propellers 312L to 315L and 312R to 315R disposed at the inner side to be larger than the revolutions per minute at the vertical takeoff and landing stage. As a result, a 'powered lift', which is an advantage of the lower propellers 312L to 315L and 312R to 315R, having a small diameter, occurs even more during forward flight.

The forward flight step may further include a step S32 of adjusting the angle of the auxiliary wings 220 and 320 included in the upper wing portion 200 and the lower wing portion 300. For example, the auxiliary vanes 220 and 320 included in the lower vane unit 300 may be controlled to rotate downward to increase the lift force. On the other hand, during cruising during the forward flight phase, the angles of the control surfaces 220 and 320 can be maintained at about zero degrees.

The forward flight step may further include a step S33 of moving the battery B disposed inside the body part 100 to the backward direction of the body part 100. [ The control unit can adjust the center of gravity of the aircraft by moving the forwardly moved battery B backward.

On the other hand, the number of revolutions per minute of the upper propeller 210 and the lower propeller 310 can be adjusted for attitude control even during forward flight. After the forward flight phase, the transition phase and the landing phase can be performed again.

FIG. 8D shows the transition from the forward flight phase to the landing phase. At this time, the rotation speed per minute of the lower propeller 310 is made larger than the rotation speed per minute of the upper propeller 210, the angle of the control surfaces 220 and 320 is adjusted to make the lift different, B can be moved in the backward direction to form a pitching moment. The pitch angle with respect to the ground surface of the body portion 100 is increased again.

8E shows the landing stage. The control unit adjusts the rotation speed of the upper propeller 210 and the lower propeller 310 to be similar to each other and adjusts the angles of the control surfaces 220 and 320 so as to change the attitude of the aircraft Can be controlled. In the landing phase, the battery B can return to the position in the take-off step S10.

According to the control method of an aircraft according to an embodiment of the present invention, the movement of the battery B using the two-layered propeller, the control surfaces 220 and 320 or the battery transfer unit 400 is controlled S10, a transition step S20, and a forward flight step S30. In particular, since the pitching moment is controlled through various control methods at the transition stage, stability in operation is increased.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: body portion 110: front end
120: tail portion 200: upper wing portion
210: upper propeller 220: upper wing control surface
300: lower wing part 310: lower propeller
320: lower wing portion control surface 400: battery transfer portion
410: holder 420: sliding part
430: Power supply

Claims (13)

A body portion whose pitching angle with respect to the ground changes according to a flight mode;
An upper wing portion and a lower wing portion connected to the body portion in a fixed wing shape;
A plurality of upper propellers and a plurality of lower propellers disposed in the form of being embedded in the upper wing portion and the lower wing portion, respectively,
The upper propeller and the lower propeller provide lift in vertical take-off mode, provide thrust in forward flight mode,
Further comprising a battery transfer unit for transferring the battery when the flight mode is changed, and a battery transfer unit disposed inside the body unit. The method according to claim 1,
Wherein the upper propeller is disposed on each of left and right sides of the upper wing portion,
Wherein at least two of the lower propellers are disposed on the left and right sides of the lower wing portion, respectively. The method according to claim 1,
Wherein when the flight mode changes from the vertical take-off and landing mode to the forward flight mode, the number of revolutions per minute of the specific upper propeller of the plurality of upper propellers is greater than the number of revolutions per minute of the lower propeller corresponding to the position of the specific upper propeller, Landing and landing dispersal propulsion aircraft. The method according to claim 1,
Wherein the upper wing portion and the lower wing portion comprise a steerable surface for controlling lift during flight. delete The method according to claim 1,
Wherein the battery transfer unit moves the battery in a forward direction of the body when the flight mode changes from the vertical take-off mode to the forward flight mode. The method according to claim 1,
Wherein the lower wing portion is disposed in front of the body portion with respect to the upper wing portion. The method according to claim 1,
The upper propeller disposed on the outermost side of the upper wing portion of the plurality of upper propellers has a longer blade length than the remaining upper propellers,
Wherein the lower propeller disposed on the outermost side of the lower wing portion of the plurality of lower propellers has a longer blade than the remaining lower propeller. A take-off step, a transition step, and a forward flight step, which are sequentially performed,
Wherein the take-off step includes rotating a plurality of upper propellers and lower propellers, which are arranged in a state that the upper wings and the lower wings,
Wherein the transition step includes the step of changing the pitch angle with respect to the ground of the body by controlling the number of revolutions per minute of the plurality of upper propellers and lower propellers,
Wherein the transferring step comprises:
Further comprising moving a battery disposed in the body portion toward a front side of the body portion by a battery transfer portion disposed inside the body portion. 10. The method of claim 9,
Wherein the transition step and the forward-
Further comprising the step of adjusting an angle of an auxiliary wing coupled to the front or rear of the upper wing portion and the lower wing portion. delete 10. The method of claim 9,
Wherein the forward flight step includes the steps of reducing the number of revolutions per minute of the upper propeller and the lower propeller disposed outermost among the plurality of upper propellers and the lower propellers, And increasing the revolutions per minute of the lower propeller. 10. The method of claim 9,
Wherein the forward flight step comprises:
Further comprising the step of moving a battery disposed within the body portion toward a rear side of the body portion.

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