JP7119793B2 - flying object - Google Patents

Description

The present invention relates to an aircraft having rotary wings, such as a multicopter.

2. Description of the Related Art In recent years, drones (multicopters) and the like have become popular as small unmanned flying objects capable of unmanned flight. Drones are used in a variety of industries, including surveying, disaster relief, research on the natural environment, sports broadcasting, and pesticide spraying.
There are various shapes in the structure of the drone body, but in general, the drone consists of a main body, a plurality of frames extending radially from the main body, and a propulsion drive provided at the tip of the frame. Prepare. The propulsion drive unit is a unit that generates lift and thrust for flight of the airframe, and includes a propeller (rotor), which is a rotating wing, and a motor that rotates the propeller.

For example, Patent Literature 1 discloses an unmanned rotary wing aircraft having four frames extending in an X shape from a main body, and a motor for rotating a propeller (rotor) attached to the tip of each frame. ing. Here, the motor is a three-phase brushless DC motor having U-phase, V-phase, and W-phase, and the rotational speed (number of rotations) of the motor is controlled by an electronic speed controller (ESC).

JP 2017-136914 A

Currently, the lifespan of drones is largely due to accidents such as damage due to crashes and missing drones. Common causes of crashes include loss of communication during flight, dead batteries, motor failure, and poor piloting. Therefore, conventionally, measures and improvements focused on the above points have been made in order to extend the life of drones.
Drones are equipped with various electrical component units, and these electrical component units generate heat when driven. Therefore, appropriately suppressing the temperature rise of the electric component unit is also an important issue for extending the life of the drone. However, conventionally, almost no countermeasures have been taken for this point.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to appropriately suppress an increase in the temperature of an electric component unit, thereby prolonging the life of an aircraft.

In order to solve the above problems, one aspect of the aircraft according to the present invention includes a main body, a plurality of frame parts extending from the main body, a rotor provided at a tip of the frame, and a rotor and the rotor. and an electrical component unit for driving the propulsion drive, wherein the frame is a hollow member having a space inside, and the frame a plurality of air supply/exhaust ports communicating between the outside of the frame portion and the space, and the electric component unit is disposed within the space of the frame portion and between at least two of the air supply/exhaust ports. The air supply/exhaust port is a cooling air intake port formed at an end portion of the frame portion on the propulsion drive unit side, for taking in the air generated by the rotation of the rotor blades as cooling air into the inside of the frame portion. Including .

In this way, by making the frame part a hollow structure and forming a plurality of air supply/exhaust ports, an air flow can be generated inside the frame part. The wind flowing inside the frame acts as a cooling wind that cools the electric component unit that is inside the frame and arranged between the two air supply/exhaust ports. Therefore, it is possible to appropriately suppress the temperature rise of the electric component unit. As a result, it is possible to extend the life of the electric component unit, and as a result, it is possible to extend the life of the aircraft on which the electric component unit is mounted.

Moreover, in the flying object described above, the electric component unit may include a speed control unit that controls the rotational speed of the motor.
The speed control unit comprises a plurality of switching elements to control the speed of rotation of the motor and is expected to generate considerable heat. In this way, the speed control unit, which generates a large amount of heat, is placed inside the frame and cooled by the cooling air flowing inside the frame. , it is possible to extend the life of the flying object.

Further, in the flying object described above, the frame portion may have the air supply/exhaust ports at the propulsion drive portion side end portion and the main body portion side end portion. In this case, the area from one end to the other end of the frame portion can be effectively used as a cooling air passage.
Further, in the flying object described above, the cooling air intake port may be formed on the upper surface of the end portion of the frame portion on the propulsion drive portion side, at a position facing the rotating rotor blade. In this case, the air supply/exhaust port can be a cooling air intake port that allows the air generated by the rotation of the rotor blades to be easily taken into the inside of the frame portion.
Further, in the flying object described above, the air supply/exhaust port may be formed in a lower surface of an end portion of the frame portion on the main body portion side. In this case, the air supply/exhaust port can be a cooling air exhaust port capable of appropriately discharging the air taken in from the cooling air intake port to the outside of the frame portion.

Further, a cooling body for cooling the electric component unit may be attached to the electric component unit. In this case, the temperature rise of the electric component unit can be suppressed more efficiently.
Furthermore, in the aircraft described above, the cooling body may be made of a carbon fiber reinforced carbon composite material. Carbon fiber reinforced carbon composites are materials with low density and high thermal conductivity. Therefore, a lightweight cooling body with high cooling efficiency can be provided, and the electric component unit can be efficiently cooled without significantly increasing the weight of the aircraft.

According to the present invention, since the electrical component unit can be forcedly air-cooled, the temperature rise of the electrical component unit can be appropriately suppressed, and the life of the aircraft can be extended.

It is a figure which shows the whole structural example of the aircraft in this embodiment. It is a figure which shows the outline of the system configuration|structure of an aircraft. FIG. 4 is a diagram showing the flow of air inside the frame. FIG. 4 is a diagram showing the flow of air inside the frame. This is an example in which a cooling body is attached to the speed control unit.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram showing an example of the overall configuration of an aircraft 10 according to this embodiment. In this embodiment, a case where the flying object 10 is a drone (multicopter) will be described.
The drone 10 includes a body portion 11 and a plurality of (four in this embodiment) frame portions 12 extending from the body portion 11 . Further, the drone 10 includes a propulsion drive section 20 provided at each tip portion of the frame portion 12 (the end portion on the side other than the main body portion 11 side).
The propulsion drive unit 20 is a unit that generates lift and thrust for flight of the airframe, and includes a motor 21 and a rotating blade (also referred to as a propeller or rotor) 22 rotated by the motor 21 . Here, the motor 21 is a three-phase brushless DC motor, and the rotation speed (number of rotations) is controlled by a controller 32, which will be described later.

Various electrical component units are mounted on the body portion 11 and the frame portion 12 . Specifically, a receiving unit 31 , a controller 32 , a sensor unit 33 and a battery unit 34 are mounted on the main body 11 . A speed control unit 35 is mounted on the frame portion 12 .
These electric component units are covered with a housing (including a cover, etc.) 13 that constitutes the main body 11 and the frame 12 .

FIG. 2 is a diagram showing an outline of the system configuration of the drone 10. As shown in FIG.
The receiving unit 31 receives a signal transmitted from an operator (not shown) and outputs the received signal to the controller 32 . Here, the pilot is a tool for the pilot to remotely operate the drone 10 . The receiving unit 31 includes an antenna for receiving signals transmitted from a pilot-operated controller.
The controller 32 includes a CPU, ROM, RAM, etc., receives signals received by the receiving unit 31 and signals detected by the sensor unit 33, and performs flight control of the drone 10 based on these signals.

The sensor unit 33 includes various sensors. For example, the sensor unit 33 includes a gyro sensor 33a, an acceleration sensor 33b, an atmospheric pressure sensor 33c, a GPS sensor 33d, and the like.
The gyro sensor 33a is, for example, a three-axis gyro, and detects the amount of change in tilt with respect to each direction of the roll axis, pitch axis, and yaw axis of the body of the drone 10 . The acceleration sensor 33b detects acceleration of the body of the drone 10 . The acceleration sensor 33b may be, for example, a three-axis acceleration sensor that detects acceleration in three directions of the XYZ axes. The atmospheric pressure sensor 33c detects atmospheric pressure and detects the altitude of the drone 10 based on the detected atmospheric pressure. The GPS sensor 33d detects the flight position of the drone 10 body.

The controller 32 determines the target rotation speed of each motor 21 based on the signal received by the receiving unit 31 and the signal detected by the sensor unit 33, and adjusts the rotation speed of each motor 21 so that it matches the target rotation speed. to control the speed control unit 35.
A speed control unit 35 is provided corresponding to each motor 21 . Each speed control unit 35 includes an inverter circuit having six switching elements in this embodiment, and a driving circuit (gate driver) for on/off controlling the switching elements. Here, the switching elements are FETs (Field Effect Transistors), MOSFETs (MOS Field Effect Transistors), IGBTs (Insulated Gate Bipolar Transistors), and the like.

The controller 32 individually controls the rotation speed (number of rotations) of each motor 21 via the speed control unit 35, so that the drone 10 can perform flight control such as takeoff, landing, forward movement, and backward movement, and roll, pitch, Attitude control such as yawing is performed.
Electric power is supplied from the battery unit 34 shown in FIG. 1 to each electric component unit (31, 32, 33, 35) shown in FIG. Battery unit 34 may be, for example, a lithium rechargeable battery. The battery unit 34 is provided at the center of the lower portion of the body portion 11 in order to stabilize the center of gravity of the aircraft. The power supply from the battery unit 34 to each electric component unit may be performed directly by wiring, or may be performed via a PMU (Power Management Unit).

By the way, as described above, the speed control unit 35 has six switching elements to control the three-phase motor over a wide speed range. A switching element is a heating element that generates heat when a current flows. Since the speed control units 35 each have six switching elements, considerable heat generation is expected. Therefore, if cooling is not performed appropriately, the temperature of the junction portion of the switching element may exceed a certain temperature, resulting in malfunction of the switching element. Moreover, if the speed control unit 35 itself becomes hot, it may cause malfunctions not only in the switching elements but also in other electrical components included in the speed control unit 35 .

In other words, in order to extend the life of the speed control unit 35, it is important to appropriately cool the switching elements and suppress an excessive temperature rise of the speed control unit 35. FIG.
In this embodiment, the frame portion 12 has a hollow structure and the speed control unit 35 is arranged inside the hollow frame portion 12 in order to suppress the temperature rise of the speed control unit 35 . The inside of the hollow frame portion 12 is used as a cooling air passage, and the speed control unit 35 is cooled by the cooling air passing inside the frame portion 12 .

FIG. 3 is a diagram showing an example of the cross-sectional structure of the frame portion 12. As shown in FIG.
The frame portion 12 is a hollow (cylindrical) member extending in one direction. The cross-sectional shape of the frame portion 12 in the direction orthogonal to the longitudinal direction is not particularly limited, and the frame portion 12 may have a square hollow structure or a circular hollow structure.
The frame portion 12 includes at least one cooling air inlet 15 and at least one cooling air outlet 16 . The cooling air intake port 15 and the cooling air exhaust port 16 are formed in the frame portion 12 respectively, and are air supply/exhaust ports that allow the outside of the frame portion 12 and the space inside the frame portion 12 to communicate with each other.

FIG. 3 shows an example in which a cooling air intake port 15 is formed at the end portion of the frame portion 12 on the propulsion drive portion 20 side, and a cooling air exhaust port 16 is formed at the end portion of the frame portion 12 on the main body portion 11 side. . The speed control unit 35 is arranged inside the frame portion 12 and between the cooling air inlet 15 and the cooling air outlet 16 .
Specifically, the cooling air intake port 15 is formed on the upper surface of the frame section 12 on the propulsion drive section 20 side and at a position facing the rotor blades 22 (directly below the rotor blades 22). The cooling air intake port 15 is also formed at a position facing the propulsion drive section 20 at the end face of the frame section 12 on the propulsion drive section 20 side. The cooling air intake 15 is formed so that part of the air generated during flight of the drone 10 enters the hollow inside of the frame part 12 .

The cooling air outlet 16 is formed on the lower surface of the frame portion 12 on the main body portion 11 side. The cooling air outlet 16 is formed so that the air taken into the inside of the frame portion 12 from the cooling air inlet 15 is discharged to the outside of the frame portion 12 .
With the above configuration, as shown in FIG. 3, during flight of the drone 10, a portion of the wind 41 generated by the rotating rotor blades 22 flows from the cooling air intake 15 formed on the upper surface of the frame portion 12 to the frame portion. Enter inside 12. Also, a part of the wind 42 generated by the rotating rotor blades 22 enters the inside of the frame portion 12 through the cooling wind intake port 15 formed in the end face of the frame portion 12 . Furthermore, part of the wind 43 generated by the forward, backward, ascending, descending movement of the machine body also enters the inside of the frame portion 12 through the cooling air inlet 15 formed in the end face of the frame portion 12 .

The wind 44 taken inside the frame portion 12 flows toward the body portion 11 inside the hollow frame portion 12 . This wind 44 acts as cooling wind for cooling the speed control unit 35 arranged inside the frame portion 12 . That is, the speed control unit 35 is appropriately cooled by the wind 44 flowing inside the frame portion 12, and the temperature rise is suppressed.
The air 45 that has cooled the speed control unit 35 is discharged from a cooling air outlet 16 formed on the main body 11 side of the frame 12 .

In the example shown in FIG. 3, the cooling air intake 15 is provided on the upper surface of the frame portion 12 (the surface facing the rotor blades 22) and the end surface of the frame portion 12 (the surface facing the motor 21 of the propulsion drive portion 20). However, the position where the cooling air intake 15 is formed is not limited to the position shown in FIG. The cooling wind intake port 15 may be formed at a position where the wind generated during the flight of the drone 10 can be taken into the inside of the frame portion 12 . Also, the number of cooling air intake ports 15 is not limited to the number (two) shown in FIG.

Further, depending on the flight state of the airframe, as shown in FIG. For example, when the fuselage is descending, air is taken in from the cooling air outlet 16 formed on the lower surface of the frame portion 12 . In this case, the wind 52 taken inside the frame portion 12 flows through the inside of the frame portion 12 toward the propulsion drive portion 20, cooling the speed control unit 35 in the process. A portion 53 of the air that has cooled the speed control unit 35 is discharged from the cooling air inlet 15 formed on the upper surface of the frame portion 12, and the remaining portion 54 is formed on the end surface of the frame portion 12. It is exhausted from the cooling air intake port 15 .
That is, depending on the flight state of the aircraft, the cooling air inlet 15 can be used as a cooling air outlet, and the cooling air outlet 16 can be used as a cooling air inlet.

As described above, the drone 10 according to the present embodiment includes a body portion 11, a plurality of frame portions 12 extending from the body portion 11, a propulsion drive portion 20 provided at each tip portion of the frame portion 12, and a propulsion drive portion 20 an electrical component unit for driving the Here, the frame portion 12 is a hollow member having a space inside, and has a plurality of air supply/exhaust ports that communicate between the outside of the frame portion 12 and the space inside. Also, the electric component unit is arranged inside (inside the space) of the frame portion 12 and between at least two air supply/exhaust ports.
Specifically, the frame portion 12 has an air supply/exhaust port at an end portion on the main body portion 11 side and an end portion on the propulsion drive portion 20 side. It is arranged between an exhaust port and an air supply/exhaust port provided on the propulsion drive unit 20 side.

In this way, by making the frame portion 12 have a hollow structure and forming a plurality of air supply/exhaust ports, an air flow is generated inside the frame portion 12 . The wind flowing inside the frame portion 12 acts as a cooling wind for cooling the electric component units arranged inside the frame portion 12 and between the two air supply/exhaust ports. As a result, the electric component unit can be forcibly air-cooled, and the temperature rise of the electric component unit can be appropriately suppressed. Therefore, it is possible to prolong the life of the electrical component unit, and as a result, it is possible to prolong the life of the drone 10 on which the electrical component unit is mounted.

Also, the electric component unit arranged inside the frame portion 12 can be a speed control unit 35 that controls the rotational speed of the motor 21 . A speed control unit 35 is provided corresponding to each of the plurality of motors 21 in order to individually control the rotational speeds of the plurality of motors 21 . Also, the motor 21 is a three-phase brushless DC motor, and the speed control unit 35 is provided with six switching elements in order to control the current flowing through the three phases of the motor 21 . Therefore, the speed control unit 35 is expected to generate considerable heat.
Therefore, by arranging the speed control unit 35 inside the frame portion 12 and cooling it with cooling air flowing inside the frame portion 12, the temperature rise of the speed control unit 35, which generates a large amount of heat, can be appropriately suppressed. , the life of the drone 10 can be effectively extended.

Also, by arranging the speed control unit 35 inside the frame portion 12 , the speed control unit 35 can be separated from the other electric component units arranged in the main body portion 11 . As a result, it is possible to suppress the switching noise of the switching elements included in the speed control unit 35 from adversely affecting the operation of other electric component units.
For example, the controller 32 monitors the current flowing through each phase of the motor 21 in order to determine whether the motor 21 is operating normally. If the speed control unit 35 is arranged near the controller 32, the controller 32 may erroneously determine the operation of the motor 21 due to the switching noise. By arranging the speed control unit 35 away from the controller 35, the erroneous determination can be suppressed.

Further, the air supply/exhaust port formed at the end portion of the frame portion 12 on the propulsion drive portion 20 side can be formed on the upper surface of the frame portion 12 at a position facing the rotating rotor blades 22 . As a result, the air supply/exhaust port can be used as a cooling air inlet that can easily take in the air generated by the rotation of the rotor blades 22 into the inside of the frame portion 12 .
In addition, the air supply/exhaust port formed at the end portion of the frame portion 12 on the main body portion 11 side can be formed on the lower surface of the frame portion 12 . As a result, the air supply/exhaust port serves as a cooling air exhaust port capable of appropriately discharging the air taken in from the cooling air intake port formed at a position facing the rotor blade 22 to the outside of the frame portion 12. can be done.
Thus, the drone 10 according to the present embodiment can reliably allow air to flow inside the frame portion 12 and appropriately cool the speed control unit 35 arranged inside the frame portion 12 .

In order to cool the speed control unit 35 more efficiently, a cooling body 36 having excellent thermal conductivity may be attached to the heat radiation surface of the speed control unit 35 as shown in FIG. The cooling body 36 may be attached to the switching element itself, which is a heating element provided in the speed control unit 35, or may be attached to a substrate on which the switching element is mounted.
Here, as the material of the cooling body 36, for example, a carbon fiber reinforced carbon composite material can be used. A carbon fiber reinforced carbon composite material is a composite material in which carbon fiber is used as a reinforcing material and carbon is used as a matrix. A carbon fiber reinforced carbon composite material is produced by molding and curing carbon fiber reinforced plastic (CFRP), followed by heat treatment in an inert atmosphere to carbonize the base material plastic. Carbon fiber reinforced carbon composite materials include C/C composite, carbon-carbon, carbon-carbon composite, reinforced carbon-carbon, RCC ) are sometimes called. In the following description, carbon fiber reinforced carbon composite materials are referred to as "C/C composites."

A method of manufacturing the C/C composite used as the cooling body 36 in this embodiment will be described below.
First, CFRP is produced. CFRP is configured by laminating a plurality of prepregs. A prepreg is a sheet-like member in which carbon fibers are impregnated with a resin while maintaining the directionality of the fibers. The resin forming the prepreg is, for example, a thermosetting epoxy resin. Thermosetting resins such as unsaturated polyesters, vinyl esters, phenols, cyanate esters, and polyimides can also be used as resins constituting the prepreg.

CFRP is formed by laminating a required number of prepreg layers (5 to 10 layers) in a mold, heating to about 120° C. to 130° C. under reduced pressure, and pressurizing (pressing) to cure. be. Here, in this embodiment, as the prepreg, a UD material (UNI-DIRECTION material) having fibers extending in only one direction is used. In this case, a plurality of UD materials are laminated so that the directions of the fibers are aligned to produce CFRP. As the prepreg, it is also possible to use a cloth material in which the fibers are laminated in different directions. However, in this case, the orientation of the fibers shall be set so as to have anisotropy.
Next, the CFRP is heat-treated at 2500° C. to 3000° C. for about two weeks to produce a C/C composite.

A C/C composite is a material that has a lower density (that is, lighter weight) and higher thermal conductivity than metal materials such as copper and aluminum that are commonly used as cooling bodies.
For example, copper has a density of about 8.9 g/cm ³ and aluminum has a density of about 2.7 g/cm ³ while a C/C composite has a density of about 1.7 g/cm ³ . Also, the thermal conductivity of copper is about 400 W/mK and aluminum is about 240 W/mK, while the C/C composite is 700 W/mK.

Conventionally, aluminum and copper, which are metals with good thermal conductivity, have been widely used as cooling bodies for cooling heat-generating elements such as switching elements. However, considering that it is mounted on the airframe of a drone, making the cooling body metal causes an increase in the weight of the airframe, which is disadvantageous. The payload is an important factor in drones, and in order to maximize the payload, it is necessary to make the weight of the drone itself as light as possible.
Even if it is known that if a cooling body is attached to the speed control unit 35, the cooling efficiency of the speed control unit 35 can be increased, and the life of the speed control unit 35 and thus the drone 10 can be further extended, cooling It cannot be installed if the body significantly increases the weight of the airframe.

The inventors have found that a C/C composite is the best material for the cooling body to solve the above problems. Since the C/C composite has high thermal conductivity as described above, it can sufficiently function as a cooling body. In addition, since it has a low density (light weight), even if it is attached to the speed control unit 35, it does not significantly increase the weight of the airframe.
The specific thermal conductivity [W·cm ³ /mK·g], which is the value obtained by dividing the thermal conductivity by the density, is 44.9 for copper, 74 for aluminum, and 411.8 for the C/C composite. Thus, the C/C composite is a material with higher thermal conductivity and lighter weight than copper and aluminum. Therefore, the C/C composite is extremely excellent as a material capable of efficiently cooling the speed control unit 35 while suppressing an increase in the weight of the airframe.

It is conceivable to select CFRP as a coolant that is lightweight and has high thermal conductivity. It does not matter. Materials used as coolants are desired to have high thermal conductivity rather than high strength. Therefore, the C/C composite is superior to CFRP as a material capable of efficiently cooling the speed control unit 35 while suppressing an increase in the weight of the airframe.

Thus, the drone 10 in this embodiment may have the cooling body 36 attached to the speed control unit 35 . Thereby, the speed control unit 35 can be cooled more efficiently.
In addition, by using a carbon fiber reinforced carbon composite material (C/C composite) as the material of the cooling body 36, not only high efficiency cooling but also the weight increase of the airframe due to attaching the cooling body 36 is minimized. be able to.

The C/C composite can have an anisotropic thermal conductivity depending on the orientation of the carbon fibers. For example, in the case of a unidirectional C/C composite using a UD material as a prepreg, the thermal conductivity is high in the direction in which the carbon fibers extend (orientation direction of the carbon fibers). Considering this, when the cooling body 36 using the C/C composite is attached to the heat radiation surface of the speed control unit 35, the orientation direction of the carbon fiber of the C/C composite should be along the direction of flow of the cooling air. You may make it attach by doing. Thereby, the speed control unit 35 can be cooled more efficiently.

Furthermore, considering the anisotropy of the thermal conductivity of the C/C composite, when the cooling body 36 using the C/C composite is used, the longitudinal direction of the cooling body 36 is the C/C composite carbon fiber orientation It may be set along the direction. That is, the cooling body 36 may have an elongated shape extending in the direction of high thermal conductivity. Thereby, the cooling efficiency by the cooling body 36 can be improved. Moreover, even in an elongated space such as the inside of the frame portion 12, the cooling body 36 can be appropriately arranged.
Moreover, unevenness (fins, blades) may be formed on the surface of the cooling body 36 . In this case, the direction in which the unevenness (fins, blades) extends may be formed along the direction in which the cooling air flows. Also in this case, the speed control unit 35 can be cooled more efficiently.

(Modification)
Although the drone 10 having the four rotor blades 22 has been described in the above embodiment, the number and configuration of the rotor blades are not particularly limited.
Also, in the above embodiment, the flying object is a drone, but the flying object is not limited to a multicopter as long as it has rotary wings. Also, the flying object is not limited to an unmanned rotorcraft.
Furthermore, in the above-described embodiment, the speed control unit 35 among the electrical component units is arranged inside (hollow portion) of the frame portion 12, but other electrical components for driving the propulsion drive section 20 are described. A structure may be employed in which units are arranged to suppress the temperature rise.

DESCRIPTION OF SYMBOLS 10... Flying object (drone) 11... Main body part 12... Frame part 15... Cooling wind intake (air supply/exhaust port) 16... Cooling air exhaust port (air supply/exhaust port) 20... Propulsion drive part 21... Motor 22 Rotor blade 31 Receiving unit 32 Controller 33 Sensor unit 34 Battery unit 35 Speed control unit 36 Cooling body

Claims (7)

a body portion, a plurality of frame portions extending from the body portion, a propulsion drive portion provided at the tip portion of the frame portion and having a rotor blade and a motor for rotating the rotor blade, and for driving the propulsion drive portion. and an electric component unit of
The frame portion is a hollow member having a space inside, and has a plurality of air supply/exhaust ports communicating between the outside of the frame portion and the space,
The electric component unit is arranged within the space of the frame portion and between at least two of the air supply/exhaust ports ,
The air supply/exhaust port is a cooling air inlet formed at the end of the frame on the propulsion drive unit side, and takes in the air generated by the rotation of the rotor blade as cooling air into the inside of the frame. an air vehicle comprising : 2. The flying object according to claim 1, wherein said electrical component unit includes a speed control unit for controlling the rotational speed of said motor. The frame portion
3. The aircraft according to claim 1, wherein the air supply/exhaust port is provided at each of the propulsion drive unit side end portion and the main body portion side end portion. 4. The apparatus according to any one of claims 1 to 3, wherein the cooling air intake port is formed on an upper surface of the end portion of the frame portion on the side of the propulsion drive portion, at a position facing the rotating blade. The aircraft according to any one of claims 1 to 3. 5. The flying object according to claim 4, wherein the air supply/exhaust port is formed in a lower surface of an end portion of the frame portion on the main body portion side. 6. The aircraft according to any one of claims 1 to 5, wherein a cooling body for cooling said electric part unit is attached to said electric part unit. 7. The aircraft according to claim 6, wherein the cooling body is made of a carbon fiber reinforced carbon composite material.

Images