KR101169742B1 - The flying object equipped coaxial duct system - Google Patents

Abstract

The present invention relates to a vehicle using a duct system for coaxial reflection, more specifically a fuselage; A lower rotor provided on a rotation shaft connected to the body; An upper rotor provided on the rotation shaft and provided on an upper portion of the lower rotor; A lower rotor blade connected to the lower rotor; An upper rotor blade connected to the upper rotor; A lower duct surrounding the lower rotor blade; And an upper duct surrounding the upper rotor blade.

Coaxial Inversion, Duct System, Wake Area, Thrust Coefficient

Description

The flying object equipped coaxial duct system

The present invention relates to a vehicle using a duct system for coaxial reflection, more specifically a fuselage; A lower rotor provided on a rotation shaft connected to the body; An upper rotor provided on the rotation shaft and provided on an upper portion of the lower rotor; A lower rotor blade connected to the lower rotor; An upper rotor blade connected to the upper rotor; A lower duct surrounding the lower rotor blade; And an upper duct surrounding the upper rotor blade.

In general, a helicopter represented by a rotor type aircraft has an advantage of being able to take place and take off and landing vertically, but has a problem in that the length of the entire fuselage is relatively long.

The reason for this is that in the case of helicopters, a tail rotor is needed to offset the very long main rotor blades and the rotational moments arising from the main rotor blades.

 In addition, since the tail rotor blade is exposed to the outside, there are many safety problems, and the output of the tail rotor blade has a disadvantage of being independent of thrust.

In addition, as described above, the fuselage includes a long problem, and there is a problem about accessibility in a building or a building, a mountainous terrain, and the like.

In order to solve the above problems to some extent, a method for miniaturization of a vehicle has been studied. For this purpose, a coaxial reversal system, that is, a coaxial reversal provided with blades in a pair of rotors rotating in opposite directions on the same axis The aircraft appeared.

Since the coaxial inverted vehicle does not require a tail rotor blade as compared to a single rotor type vehicle, it was possible to achieve the miniaturization of the vehicle to some extent.

However, in the case of the conventional coaxial reverse aircraft, there was a problem that the thrust is reduced.

It is an object of the present invention to solve the problems as described above, and to provide an aircraft that can easily access to a specific place through the miniaturization of the rotor type aircraft, and at the same time can reinforce thrust during in-flight flight.

Another object is to provide a vehicle having excellent flight stability in stationary flight and high speed flight.

In addition, another object is to provide a vehicle that can protect the rotor blades and reduce noise.

The objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

The present invention for achieving the above object, the body; A lower rotor provided on a rotation shaft connected to the body; An upper rotor provided on the rotation shaft and provided on an upper portion of the lower rotor; A lower rotor blade connected to the lower rotor; An upper rotor blade connected to the upper rotor; A lower duct surrounding the lower rotor blade; And an upper duct surrounding the upper rotor blade.

In the present invention, preferably the vertical width of the lower duct is larger than the vertical width of the upper duct.

In the present invention, preferably provided in a predetermined portion of the body, characterized in that it further comprises an electric motor for transmitting a rotational force to the rotating shaft.

In the present invention, preferably provided in a predetermined portion of the main body, characterized in that it further comprises a battery for supplying power to the electric motor.

In the present invention preferably further comprises a control box for controlling the body.

In the present invention, preferably, the control box is controlled using a manned or unmanned system.

In the present invention preferably further comprises a transmitting and receiving antenna provided in a predetermined portion of the lower duct or the upper duct.

In the present invention, the fuselage is preferably made of a streamline so that the wake by the blade is not transmitted to the occupant.

The following excellent effects of the present invention.

First, due to the miniaturization of the aircraft according to the present invention, accessibility to a specific region or place and thrust is superior to conventional coaxial inverted vehicles.

In addition, the vehicle according to the present invention has an excellent flight stability in stationary flight and high speed flight.

In addition, it is safe to protect the rotor blades, there is an excellent effect of reducing noise.

Although the terms used in the present invention have been selected as general terms that are widely used at present, there are some terms selected arbitrarily by the applicant in a specific case. In this case, the meaning described or used in the detailed description part of the invention The meaning must be grasped.

Hereinafter, with reference to the preferred embodiments shown in the accompanying drawings will be described in detail the technical configuration of the present invention.

First, FIG. 1 is a vehicle 100 using a duct system for coaxial inversion (coaxial inversion in the description of the present invention means rotation in opposite directions on the same axis) according to an embodiment of the present invention. Is the overall configuration diagram.

As shown in FIG. 1, the fuselage 110 is a space for a manned vehicle to be boarded by an operator for manipulating the vehicle 100, and in the case of an unmanned aircraft, a space in which an unmanned system is mounted.

The body 110 may be provided using a variety of materials including a lightweight alloy having excellent strength and durability.

On the other hand, the body 110 is made of a streamline to smooth the flow of the downward flow by the blade to be described later, so that the wake is not transmitted to the operator.

Of course, the shape of the body 110 may be formed in a variety of shapes.

On the other hand, a rotating shaft protrudes from the upper portion of the body 110, a predetermined portion of the body 110 is provided with an electric motor 160 for transmitting a rotational force to the rotating shaft.

In this case, the driving of the electric motor 160 and the overall driving of the fuselage 110 (for example, a change of direction in a vertical flight and a horizontal flight, etc.) are provided in a control box 180 provided at a portion of the fuselage 110. Is controlled by

In addition, a portion of the body 110 includes a battery 170 for supplying power to the electric motor 160.

Although an embodiment of the present invention has been described in detail with respect to the electric motor 160 as a rotational force transmission means of the rotary shaft, as a means for transmitting the rotational force to the rotary shaft can be used a variety of rotational force transmission means including a variety of engines and the like. .

On the other hand, the lower rotor 120 is interlocked with the rotating shaft is mounted on the rotating shaft protruding to the upper portion of the body 110.

At this time, the lower rotor (120) is coupled to the lower rotor blade (blade) 121 of a predetermined length, and generates a thrust for raising the body (110).

In addition, the upper rotor 130 is provided on the same rotary shaft as the lower rotor 120 at the upper portion of the lower rotor 120.

In addition, the upper rotor 1300 is coupled to the upper rotor blade 131 of the same length as the lower rotor blade 121, so that the thrust for raising the body 110 together with the lower rotor blade 121. Generate.

In this case, although the lower rotor 120 and the upper rotor 130 are provided on the same rotation axis and rotate at the same rotational speed, the rotation directions rotate in opposite directions.

The reason why the upper and lower rotors can rotate in opposite directions while being provided on the same rotation shaft is that the lower rotor 120 is provided with an inverting device (which can be reversed).

More specifically, the upper rotor 130 is fixed to the rotating shaft without a separate device, but the inverting device of the lower rotor 120 has the rotating shaft penetrates to the inner center, provided on the rotating shaft A first tooth rotates a second tooth provided in the reversing apparatus, and the second tooth rotates a third tooth provided in the lower rotor 120.

 That is, the upper rotor 130 rotates in the same direction as the rotary shaft, but the lower rotor 120 is provided with an inverting device so that the upper rotor 130 rotates at the same rotational speed but the rotation direction is reversed.

In general, a single-axis rotor vehicle rotates the fuselage with the rotational moment of the single rotor blade, so a tail rotor blade is required to prevent this.

However, in the case of the coaxial inverted aircraft 100, the tail rotor blade is not necessary to offset the rotation moment, and as a result, the size and length of the aircraft can be reduced, thereby miniaturizing.

On the other hand, the upper portion of the body 110 is provided with a lower duct 140 surrounding the lower rotor blade 121 and an upper duct 150 surrounding the upper rotor blade 131.

At this time, the lower duct 140 and the upper duct 150 is a cylindrical having a diameter larger than the rotation radius of the blades 121, 131 in order not to interfere with the rotation of the blades (121, 131) It is provided with.

Meanwhile, the ducts 140 and 150 may be provided as one cylindrical duct so as to surround the lower rotor blade 121 and the upper rotor blade 131 at the same time.

However, in an embodiment of the present invention, the blades 121 and 131 are separately provided to surround each other, and the vertical widths of the ducts 140 and 150 may be provided in the same manner, which will be described later. In the most preferred embodiment of the present invention for increasing the thrust of the vehicle 100, the vertical width of the lower duct 140 is provided larger than the vertical width of the upper duct 150.

The reason for this arrangement is to provide the lower duct 140 larger than the width of the upper duct 150, thereby increasing the flow rate between the upper duct 150 and the lower duct 140 and also lower duct ( Increasing the diffusion of the flow from 140 results in an increase in wake area, which in turn has the effect of increasing thrust of the vehicle 100.

In this regard, FIG. 2 is a computational flow analysis result showing the difference in wake area.

First, Figure 2 (a) shows the wake area in the case of having the same width of the lower duct 140 and the upper duct 150 in the vehicle 100 according to an embodiment of the present invention, 2B is a view showing the wake area when the vertical width of the lower duct 140 is greater than the vertical width of the upper duct 150.

As shown in FIG. 2, the air vehicle 100 according to the most preferred embodiment of the present invention has a wake area having a width of the lower duct 140 larger than that of the upper duct 150 as described above. It can be seen that the increase.

For reference, [Table 1] below is the result of numerical calculation of thrust factor (CT) and wake area, which are the criteria for increasing thrust.

First, Table 1 below shows coaxial rotor without duct, coaxial rotor with single duct, and ducts with the same width. Coaxial rotor with twin ducts with system and coaxial rotor with double ducts with duct system whose width of the lower duct is greater than the width of the upper duct.

Table 1 Comparison of Total Thrust Coefficients (CT) and Wake Areas

Trust coefficient (CT) Increasing rate [%] Wake area [㎡] Increasing rate [%] Coaxial rotor without duct 0.012042 - 39.33 - Coaxial rotor with single duct
0.012411
3.06
61.51
56.39 Coaxial rotor with twin duct
0.013062
8.47
67.65
72.01 Coaxial rotor  with double duct
0.013230
13.08
70.14
80.88

As a result, the thrust coefficient CT of the coaxial rotor with double duct equipped with the duct system having a width of the lower duct 140 according to the most preferred embodiment of the present invention is larger than the width of the upper duct 150. It can be seen that the increase rate is the highest.

Meanwhile, the lower duct 140 and the upper duct 150 are fixed to each other, and the fixed ducts 140 and 150 are fixed on the body 110 or the rotating shaft.

In addition, the ducts 140 and 150 surround the blades 121 and 131 to prevent the blades 121 and 131 from being damaged when colliding with an unspecified object due to immature operation of the vehicle 100. It also serves to reduce the noise due to the high speed rotation of the rotors (120, 130) or the blades (121, 131).

In addition, when the vehicle 100 is controlled by a manned part of the lower duct 140 or the upper duct 150, when smooth communication between the control site and the occupant or the vehicle 100 is controlled unmanned, Transmitting and receiving antenna 190 for smooth control of the vehicle 100 is provided.

As a result, the aircraft 100 using the duct system for the coaxial transfer according to an embodiment of the present invention is unlikely to require a tail rotor blade unlike the conventional single rotor type vehicle, and thus can be miniaturized, thereby providing excellent accessibility to a specific region or place. something to do.

In addition, the thrust is superior to the coaxial inverted vehicle is not provided with a duct system according to an embodiment of the present invention, excellent flight stability in stationary flight and high-speed flight. In addition, by providing the duct system can protect the rotor blade is safe, there is an excellent effect that the noise is reduced.

As described above, the present invention has been illustrated and described with reference to preferred embodiments, but is not limited to the above-described embodiments, and is provided to those skilled in the art without departing from the spirit of the present invention. Various changes and modifications are possible by this.

1 is an overall configuration diagram of a vehicle using a duct system for a coaxial transfer according to an embodiment of the present invention.

2 is a computational flow analysis result showing the difference in wake area.

Claims (8)

In a rotorcraft that inverts at the same rotational speed on the same axis, fuselage; A lower rotor provided on a rotation shaft connected to the body; An upper rotor provided on the rotation shaft and provided on an upper portion of the lower rotor; A lower rotor blade connected to the lower rotor; An upper rotor blade connected to the upper rotor; A lower duct surrounding the lower rotor blade; And And an upper duct surrounding the upper rotor blade and spaced apart from the lower duct by a predetermined distance. The lower duct and the upper duct diameters are the same, and the distance between the lower duct and the upper duct is less than the vertical width of the lower duct or the upper duct, the vehicle using a coaxial reflector duct system. The method of claim 1, And a vertical width of the lower duct is larger than a vertical width of the upper duct. 3. The method according to claim 1 or 2, Is provided on a predetermined portion of the fuselage, the vehicle using a duct system for the coaxial reflection, characterized in that it further comprises an electric motor for transmitting a rotational force to the rotating shaft. The method of claim 3, wherein Is provided on a predetermined portion of the fuselage, the vehicle using a coaxial refrigeration duct system, characterized in that it further comprises a battery for supplying power to the electric motor. 3. The method according to claim 1 or 2, Air vehicle using a duct system for the coaxial reflection further comprises a control box for controlling the fuselage. 6. The method of claim 5, The control box is a vehicle using a duct system for the coaxial reflection, characterized in that controlled using a manned or unmanned system. 3. The method according to claim 1 or 2, Air vehicle using a coaxial reflection duct system, characterized in that it further comprises a transmitting and receiving antenna provided in a predetermined portion of the lower duct or the upper duct. 3. The method according to claim 1 or 2, The fuselage is a vehicle using a duct system for a coaxial reflection, characterized in that the streamlined form so that the wake by the blade is not transmitted to the occupant.

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