KR20220057200A - Vertical takeoff and landing aircraft - Google Patents

Abstract

According to an embodiment of the present invention, a vertical takeoff and landing aircraft including a fuselage comprises: a front ducted fan located in the front of the fuselage; a rear ducted fan located in a rear portion of the fuselage relative to the front ducted fan; a pusher propeller provided at a rear end of the fuselage; and a drive engine capable of driving a drive engine shaft connected to the pusher propeller through a rear duct of the rear ducted fan along the fuselage. A front fan driveshaft of the front ducted fan can be coupled or uncoupled from the drive engine shaft through a first clutch, and a rear fan driveshaft of the rear ducted fan can be coupled or uncoupled from the drive engine shaft through a second clutch. Therefore, the vertical takeoff and landing aircraft can effectively implement a structure for power transmission/release between the ducted fans and the pusher propeller, thereby enabling high-speed flight requiring high power.

Description

Vertical takeoff and landing aircraft

The present invention relates to a vertical take-off and landing airplane, and more particularly, to a power transmission structure of the vertical take-off and landing airplane.

A vertical take-off and landing airplane is an airplane that can ascend or descend vertically without glide during take-off and landing. As an airplane taking only the bay, its utilization is increasing.

4 and 5 show an example of a vertical take-off and landing aircraft disclosed in Korean Patent Publication No. 2041203.

A conventional vertical take-off and landing aircraft has a ducted pan 400 that can be tilted on both sides of a main wing 130 and a tail wing, respectively, and a tilting unit 300 and a driving unit 310 for tilting the ducted fan 400 and a rotation support 320 .

However, the conventional vertical take-off and landing aircraft having this configuration is equipped with a ducted fan on the wing, so high-speed flight using the wing is impossible. Even if a pusher propeller is mounted on an aircraft, the power transmission of the ducted fan must be turned off for high-speed flight and power must be transmitted only to the pusher propeller, but the complexity of the structure to connect the power structure to the wing-side ducted fan However, it still has problems such as an increase in aircraft size and load due to this. In particular, this point can be called a fatal disadvantage in that the size and load management of the aircraft is important in order to realize a compact airplane and to enable high-speed flight.

For reference, FIGS. 4 and 5 correspond to FIGS. 2 and 3 of the Korean Patent Publication, respectively, and for convenience of explanation, reference numerals and the like are indicated without modification. And even if the same reference numerals as used in the description of the present invention to be described later are used, they do not refer to the same components.

Korea Patent No. 2041203 (2019.11.06)

The present invention is to solve the problems of the prior art as described above, and an object of the present invention is to effectively implement a structure for power transmission/release between a ducted fan and a pusher propeller to enable high-speed flight requiring high power, and in particular , to provide a vertical take-off and landing airplane that can be implemented with a small aircraft.

In order to achieve the above object, a vertical take-off and landing airplane according to an embodiment of the present invention includes a fuselage, a front ducted fan positioned in front of the fuselage, and a rear of the fuselage relative to the front ducted fan A rear ducted fan located in the fuselage, a pusher propeller provided at the rear end of the fuselage, and a driving engine shaft connected to the pusher propeller through the rear duct of the rear ducted fan along the fuselage can be driven a driving engine; wherein a front fan driving shaft of the front ducted fan may be coupled to or disengaged from the driving engine shaft through a first clutch, and a rear fan driving shaft of the rear ducted fan may be coupled to or disengaged from the driving engine shaft through a second clutch. It is characterized in that it can be coupled to or disconnected from the drive engine shaft.

In addition, when the vertical take-off and landing plane is viewed from above in a plan view, the front ducted fan, the driving engine, the rear ducted fan, and the pusher propeller are arranged in a line from front to rear on the fuselage in the order do it with

In addition, the front ducted fan includes a front duct, a front fan, the front fan drive shaft connected to the front fan, a front gearbox for converting a power direction of the front fan drive shaft to the drive engine shaft direction, and the front gearbox It characterized in that it further comprises a front gearbox connection shaft connected to.

In addition, the rear ducted fan may further include a rear fan, the rear fan drive shaft connected to the rear fan, and a rear gearbox for converting a power direction of the rear fan drive shaft to the drive engine shaft direction. .

In addition, the second clutch is characterized in that it is located inside the rear gearbox.

In addition, a third clutch may be further provided between the rear duct and the pusher propeller.

In addition, the drive engine shaft is characterized in that it extends through the second clutch of the rear ducted fan.

One embodiment of the method for controlling the above-described vertical take-off and landing airplane is to release the coupling of the third clutch during vertical take-off and landing so that the power from the driving engine is not transmitted to the pusher propeller, and the third clutch during cruising It is characterized in that by maintaining the coupling of the power from the driving engine is transmitted to the pusher propeller.

In addition, when the pitch angle of the vertical take-off and landing plane is increased, the first clutch is engaged and the second clutch is disengaged, and the power from the driving engine is transmitted only to the front ducted fan. Conversely, when the pitch angle of the vertical take-off and landing plane is reduced, the second clutch is engaged and the first clutch is disengaged, so that power from the driving engine is transferred to the rear ducted fan. It is characterized in that only it is transmitted.

The vertical take-off and landing airplane according to an embodiment of the present invention having the above configuration has the following effects.

The present invention minimizes the components of the internal power transmission device by arranging the front ducted fan, the driving engine, the rear ducted fan, and the pusher propeller coaxially along the fuselage, thereby reducing the weight and structure of vertical take-off and landing airplanes, particularly small vertical take-off and landing airplanes. simplification can be achieved.

In addition, by arranging the front and rear ducted fans on the fuselage, the utilization of the wings can be maximized.

In addition, the pusher propeller can be directly connected to the driving engine through the rear ducted fan, and whether the front and rear ducted fans are driven can be controlled independently of the pusher propeller, so that particularly high output and high speed flight can be achieved. .

On the other hand, the present invention, although not explicitly described, includes other effects that can be expected or derived from the above-described configuration of the present invention.

1 is a schematic diagram of a vertical take-off and landing airplane according to an embodiment of the present invention.
FIG. 2 is a top plan view of the vertical take-off and landing plane of FIG. 1 .
3 is a schematic diagram illustrating a power transmission structure of the vertical take-off and landing airplane of FIG. 1 .
4 and 5 are examples of a conventional vertical take-off and landing airplane.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can practice. However, the present invention may be embodied in several different forms and is not limited to the embodiments described herein.

1 is a schematic diagram of a vertical take-off and landing airplane according to an embodiment of the present invention, FIG. 2 is a plan view looking down from the top of the vertical take-off and landing airplane of FIG. 1, and FIG. 3 is a schematic diagram showing the power transmission structure of the vertical take-off and landing airplane of FIG. am.

As shown in FIG. 1 , a vertical take-off and landing airplane 100 (hereinafter simply referred to as 'this vertical take-off and landing airplane') according to an embodiment of the present invention includes a body part 1, and a main wing part 2 ) and the tail wing portion (3) may be further included. For reference, although not shown, the main wing portion 2 may be provided with an aileron, and the tail wing portion 3 may be provided with an elevator (elevator) and rudder (rudder), which are irrelevant to the gist of the present invention. Further description will be omitted.

1 and 2, the vertical take-off and landing airplane 100 is a front ducted fan 4, a rear ducted fan 5, and a pusher propeller. ) (6), and a driving engine (8).

The front ducted fan (4) is located in front of the body part (1) relative to the rear ducted fan (5).

The rear ducted fan 5 is located at the rear of the fuselage 1 relative to the front ducted fan 4 .

A pusher propeller 6 may be provided at the rear end of the fuselage 1 , and provides thrust during cruising of the present vertical take-off and landing airplane 100 .

As shown in FIG. 3 , the driving engine 8 passes through the rear duct 52 of the rear ducted fan 5 along the fuselage 1 and the driving engine shaft 7 connected to the pusher propeller 6 . can drive In this way, by disposing the driving engine shaft 7 through the rear duct 52, the power transmission structure can be implemented in a compact manner, thereby reducing the weight of the airplane and simplifying the structure.

Meanwhile, the front fan drive shaft 41 of the front ducted fan 4 may be coupled to or disconnected from the drive engine shaft 7 through a clutch (first clutch) 9 . Similarly, the rear fan drive shaft 51 of the rear ducted fan 5 may be coupled to or disconnected from the drive engine shaft 7 through the clutch (second clutch) 10 .

In addition, as shown in FIG. 2 , when the vertical takeoff and landing airplane 100 is viewed from above in a plan view, the front ducted fan 4 , the driving engine 8 , the rear ducted fan 5 , and the pusher propeller (6) It is arranged in a line from front to back on the body part 1 in order.

As shown in FIG. 3 , the front ducted fan 4 includes a front duct 45 , a front fan 42 that generates an air flow from the inside of the front duct 45 toward the ground, and the front fan The front fan drive shaft 41 connected to (42), the front gearbox 43 for converting the power direction of the front fan drive shaft 41 to the drive engine shaft 7 direction, and the front connected to the front gearbox 43 It includes a gearbox connection shaft (44). For reference, the front gearbox 43 may include a front bevel gear wheel, a front bevel gear pinion, and the like.

The rear ducted fan 5 includes a rear duct 52 , a rear fan 53 generating an air flow from the inside of the rear duct 52 toward the ground, and a rear fan driving shaft connected to the rear fan 53 . (51), and a rear gearbox (54) for converting the power direction of the rear fan drive shaft (51) to the drive engine shaft (7) direction. For reference, the rear gearbox 54 may include a rear bevel gear wheel, a rear bevel gear pinion, and the like.

Here, in the case of the front ducted fan 4, the front gearbox connecting shaft 44 connected to the front gearbox 43 is provided, and the clutch is engaged or disengaged to the driving engine shaft 7 through this, whereas, The rear ducted fan 5 does not have a component corresponding to the front gearbox connecting shaft 44 . That is, referring to FIG. 3 , since the driving engine shaft 7 extends through the rear gearbox 54 , that is, the second clutch 10 , there is no need to separately provide a gearbox connection shaft. Accordingly, the structural features of the present invention can achieve structural simplification and load reduction of the present vertical take-off and landing airplane 100 . For this reason, unlike the first clutch 9, the second clutch 10 can be located inside the rear gearbox 54, which can also make the structure of the vertical take-off and landing airplane 100 more compact. there is.

Meanwhile, the driving engine 8 drives (provides rotational force) the driving engine shaft 7 through the engine reduction gearbox 81 .

If necessary, although not shown, a clutch (third clutch) may be provided between the rear duct 52 and the pusher propeller 6 in order to block power transmission to the pusher propeller 6 . For reference, reference numeral 11 in FIG. 3 indicates a pusher propeller drive shaft.

Hereinafter, the operation and control method of the vertical take-off and landing airplane 100 according to an embodiment of the present invention having the above-described configuration will be exemplarily described. For reference, the present vertical take-off and landing airplane 100 has been described as having the third clutch between the rear duct 52 and the pusher propeller 6, but this may be omitted so that the pusher propeller 6 is always driven. There will be.

First, during take-off and landing of the present vertical take-off and landing airplane 100, the driving engine 8 is operated to drive the engine driving shaft 7 through the engine reduction gear box 81.

At this time, the first clutch 9 is engaged to transmit the power of the drive engine shaft 7 to the front fan drive shaft 41 , and the second clutch 10 is coupled to transmit the power of the drive engine shaft 7 to the rear It is transmitted to the gearbox 54 . Through this, by operating the front ducted fan 4 and the rear ducted fan 5, it is possible to obtain lift necessary for take-off. For reference, it may be considered to block power transmission to the pusher propeller 6 by leaving the third clutch in a disengaged state.

Next, when cruising after take-off of the present vertical take-off and landing airplane 100, particularly at high-speed cruising, the first clutch 9 and the second clutch 10 are respectively released to increase the power of the driving engine shaft 7 to the front duck. It blocks transmission to the ducted pan (4) and the rear ducted pan (5). And the third clutch is placed in the engaged state so that the power of the driving engine shaft 7 is transmitted to the pusher propeller 6 . Alternatively, the third clutch configuration may be omitted so that the power of the driving engine shaft 7 is always transmitted to the pusher propeller 6 . Through this, the power of the driving engine shaft 7 can be concentrated only on the driving of the pusher propeller 6, and in particular, high-speed flight of a small airplane can be easily achieved.

In addition, when the pitch angle is increased during cruising of the present vertical take-off and landing airplane 100, the first clutch 9 is engaged and the second clutch 10 is disengaged, and the driving engine 8 By allowing the power from the air to be transmitted only to the front ducted fan 4, the nose of the airplane can form an elevation angle.

Conversely, when the pitch angle of the vertical take-off and landing airplane 100 is reduced, the second clutch 10 is engaged and the first clutch 9 is disengaged, so that the power from the driving engine 8 is It may be transmitted only to the rear ducted fan 5 so that the nose of the airplane forms a descending angle.

On the other hand, the present vertical take-off and landing airplane 100 may be separately provided with a control unit for controlling the engagement/disengagement of the clutch and for controlling the operation of the driving engine.

As described above, in this vertical take-off and landing airplane, the front ducted fan, the driving engine, the rear ducted fan, and the pusher propeller are arranged in a line from the front to the rear in the fuselage, and the drive shaft connected to the pusher propeller passes through the rear ducted fan. The structure was simplified by placing the second clutch in the rear gearbox and allowing the drive shaft to be directly connected to the pusher propeller. Also, by engaging or disengaging the clutch, it is optimized for various flight conditions such as take-off and landing and high-speed cruising. configuration was achieved.

Although preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention as defined in the following claims are also provided. is within the scope of the

1. fuselage
2...Main wing
3...tail wing
4...Front Ducted Fan
5...rear ducted fan
6...Pusher propeller
7... drive engine shaft
8... drive engine
9... first clutch
10...2nd clutch

Claims (9)

A vertical take-off and landing airplane including a fuselage,
A front ducted fan located in front of the fuselage,
a rear ducted fan positioned at the rear of the body relative to the front ducted fan;
A pusher propeller provided at the rear end of the fuselage, and
A driving engine capable of driving a driving engine shaft connected to the pusher propeller through the rear duct of the rear ducted fan along the fuselage
includes,
The front fan drive shaft of the front ducted fan may be coupled to or disconnected from the drive engine shaft through a first clutch,
The rear fan driving shaft of the rear ducted fan may be coupled to or disengaged from the driving engine shaft through a second clutch.
vertical takeoff and landing plane. In claim 1,
When the vertical take-off and landing plane is viewed from above in a plan view, the front ducted fan, the driving engine, the rear ducted fan, and the pusher propeller are arranged in a line from front to rear on the fuselage in the order
vertical takeoff and landing plane. In claim 2,
The front ducted fan,
front duct,
front fan,
the front fan drive shaft connected to the front fan;
A front gearbox for converting the power direction of the front fan drive shaft to the drive engine shaft direction, and
Front gearbox connecting shaft connected to the front gearbox
A vertical take-off and landing plane further comprising a. In claim 2,
The rear ducted fan,
rear fan,
the rear fan drive shaft connected to the rear fan, and
A rear gearbox for converting the power direction of the rear fan drive shaft to the drive engine shaft direction
A vertical take-off and landing plane further comprising a. In claim 4,
The second clutch is a vertical take-off and landing airplane located inside the rear gearbox. In claim 1,
A vertical take-off and landing airplane that may further include a third clutch between the rear duct and the pusher propeller. In claim 1,
The drive engine shaft extends through the second clutch of the rear ducted fan. As a method of controlling the vertical take-off and landing airplane according to claim 6,
At the time of vertical take-off and landing, the coupling of the third clutch is released so that the power from the driving engine is not transmitted to the pusher propeller,
When cruising, the third clutch is maintained to be engaged so that the power from the driving engine is transmitted to the pusher propeller.
Control method for vertical take-off and landing airplanes. In claim 8,
When the pitch angle of the vertical take-off and landing plane is increased, the first clutch is engaged and the second clutch is disengaged, so that the power from the driving engine is transmitted only to the front ducted fan, ,
Conversely, when the pitch angle of the vertical take-off and landing plane is reduced, the second clutch is engaged and the first clutch is disengaged, so that the power from the driving engine is transmitted only to the rear ducted fan. doing
Control method for vertical take-off and landing airplanes.

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