JP7221568B2 - flight device - Google Patents

Description

TECHNICAL FIELD The present invention relates to an engine-mounted self-contained flight device, and more particularly, a so-called hybrid engine-mounted self-contained flight device in which a main rotor is driven by an engine and a sub-rotor is rotated by electric power obtained from a generator driven by the engine. Regarding the device.

2. Description of the Related Art Self-contained flight devices capable of unmanned flight in the air have been conventionally known. Such a self-contained flight device can fly in the air with the thrust of a rotor that rotates about a vertical axis.

Application fields of such self-contained flight devices include, for example, the transportation field, the surveying field, and the photography field. When applying the self-contained flying device to such fields, the flying device is equipped with surveying equipment and photographing equipment. By applying the flying device to such fields, it is possible to fly the flying device to areas inaccessible to humans, and to carry out transportation, photographing, and surveying of such areas. Inventions relating to such a self-contained flight device are described in, for example, Patent Document 1 and Patent Document 2.

In a typical self-contained flight device, the rotor is rotated by electric power supplied from a storage battery mounted on the flight device. However, since the supply of energy from storage batteries is not always sufficient, self-contained flight devices equipped with an engine have also emerged in order to achieve continuous flight over a long period of time. In such a self-contained flight device, the driving force of the engine rotates the generator, and the electric power generated by the generator rotates the rotor. A self-contained flying device having such a configuration is also called a series drone because an engine and a generator are connected in series to a path through which energy is supplied from a power source to a rotor. By using such a self-contained flight device to perform photographing and surveying, it is possible to perform photographing and surveying over a wide range. A flight device equipped with an engine is described, for example, in Patent Document 3.

JP 2012-51545 A JP 2014-240242 A JP 2011-251678 A

In view of the current situation in which the applications of self-contained flight devices are expanding, self-contained flight devices are required to increase the weight of cargo that can be carried, that is, to increase the payload. Furthermore, self-contained flight devices are also required to fly continuously for long periods of time in order to fly long distances.

However, in a battery-powered self-contained flight device having only a storage battery as a drive energy source for the rotor, the energy obtained from the battery is not so large, so there is a problem that the payload and continuous flight time are small. For example, a battery-powered self-contained flight device has a payload of about 10 kg and a continuous flight time of about 20 minutes.

In addition, in a series-type self-contained flight device that rotates a rotor using electric power generated by an engine, the engine is the driving source, so the payload can be relatively large, and the continuous flight time is relatively long. can do. For example, the payload of a series self-contained flight device is about 20 kg, and the continuous flight time is about one hour. However, in a series-type self-contained flight device, the energy transmitted to the rotor passes through the engine, generator, power conditioner, and motor, so energy loss occurs depending on the efficiency of the generator and power conditioner. Therefore, the series-type self-contained flying device has the problem that the energy efficiency as a whole is not high and it is not easy to increase the payload.

Furthermore, a hybrid autonomous flying device comprising an engine-driven rotor and a motor-driven rotor has also been developed. It wasn't easy to do it consistently.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances. To provide a type flight device.

The present invention comprises a main rotor that provides a main thrust to an airframe, a sub-rotor that controls the attitude of the airframe, an engine that generates energy for rotating the main rotor, and an arithmetic control unit that controls the rotation of the sub-rotor. , a generator, a power converter, a motor, and a surplus power consumption circuit, wherein the main rotor rotates by being drivingly connected to the engine, and the power converter converts the electric power generated by the generator, the sub-rotor is rotated by the motor driven by the electric power converted by the electric power converter , and when the flight device is floating in the air, the The surplus power consumption circuit is characterized by consuming part of the power generated by the generator and converted by the power converter .

The present invention comprises a main rotor that provides a main thrust to an airframe, a sub-rotor that controls the attitude of the airframe, an engine that generates energy for rotating the main rotor, and an arithmetic control unit that controls the rotation of the sub-rotor. , a generator, a power converter, a motor, and a surplus power consumption circuit, wherein the main rotor rotates by being drivingly connected to the engine, and the power converter converts the electric power generated by the generator, the sub-rotor is rotated by the motor driven by the electric power converted by the electric power converter , and when the flight device is floating in the air, the The surplus power consumption circuit is characterized in that the engine and the power converter can stably operate by consuming part of the power generated by the generator and converted by the power converter. and

According to the present invention, it is possible to stabilize the position and attitude of an autonomous flying device in the air.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the self-supporting flight device which concerns on embodiment of this invention, (A) is a perspective view which shows a self-supporting flight device, (B) is a top view. FIG. 2 is a diagram showing the self-contained flight device according to the embodiment of the present invention, and is a block diagram showing the connection configuration of each part. BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the self-supporting flight device which concerns on embodiment of this invention, (A) is side sectional drawing which shows the engine mounted, (B) is its upper sectional drawing. BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the self-supporting flight device which concerns on embodiment of this invention, (A) is side sectional drawing which shows the other mounted engine, (B) is its upper sectional drawing. FIG. 4 is a side cross-sectional view showing still another engine mounted on the self-contained flight device according to the embodiment of the present invention. BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the self-contained flight device which concerns on embodiment of this invention, (A) shows the space fixed coordinate system, (B) has shown the body fixed coordinate system. BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the self-contained flight device which concerns on embodiment of this invention, (A) is a side view which shows the body inclined 10 degrees, (B) is a graph which shows a time-dependent change of power. BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the self-contained flight device which concerns on embodiment of this invention, (A) is a side view which shows the body inclined 35 degrees, (B) is a graph which shows a time-dependent change of power.

The configuration of the engine-mounted self-contained flying device of this embodiment will be described below with reference to the drawings. In the following description, parts having the same configuration are denoted by the same reference numerals, and repeated descriptions are omitted. In the following description, up, down, front, back, left, and right directions are used, but these directions are for convenience of explanation. Also, in the following description, the engine-mounted self-contained flight device will be referred to as self-contained flight device 10 . Engine-powered self-contained flight devices are also referred to as drones.

A schematic configuration of an autonomous flight device 10 according to the present embodiment will be described with reference to FIG. FIG. 1(A) is a perspective view showing the entire self-contained flight device 10, and FIG. 1(B) is a top view of the self-contained flight device 10. FIG.

Referring to FIG. 1A, an autonomous flying device 10 is a so-called hybrid autonomous flying device. That is, the main rotor 14A and the like are connected to the engine 30 for driving, while the sub-rotor 15A and the like are supplied with electrical energy from the engine 30 via the generator 16A and the like. In the following description, the main rotor 14A etc. may be simply referred to as the main rotor 14, and the sub-rotor 15A etc. may be simply referred to as the sub-rotor 15 in some cases. Here, the left-right direction on the paper surface is the first direction in which the respective engine parts forming the engine 30 are aligned, and the front-rear direction on the paper surface is the second direction.

The self-contained flight device 10 includes a frame 11, an engine 30 disposed substantially in the center of the frame 11, a generator 16A and the like driven by the engine 30, and a sub-rotor rotated by electric power generated from the generator 16A and the like. 15 and a main rotor 14 that rotates by being drivingly connected to the engine 30 .

The frame 11 is formed in a frame shape so as to support the engine 30, the generator 16A, various wirings and control boards (not shown here), and the like. As the frame 11, a frame-shaped metal or resin is adopted. A skid 18 that contacts the ground when the self-supporting flight device 10 touches the ground is formed at the lower end portion of the frame 11 . The frame 11 includes a main frame 12A that supports the main rotor 14 and the like, and a subframe 13A that supports the subrotor 15 and the like. The configuration of the mainframe 12A etc. and the subframe 13A etc. will be described later.

The engine 30, various wirings, a control board (not shown here), and the like are housed in the casing 17. As shown in FIG. The casing 17 is made of, for example, a synthetic resin plate molded into a predetermined shape and fixed to the center of the frame 11 . Here, the casing 17 and members incorporated therein are referred to as a main body portion 19 .

Above the engine 30, generators 16A and 16B are arranged. The generators 16A and 16B are rotated by the engine 30 to generate power. Electric power generated from the generators 16A and 16B is supplied to the motor 21 and the like that rotate the sub-rotor 15A and the like. The electric power is also supplied to an arithmetic control device or the like that controls the rotation of the sub-rotor 15A or the like.

The main frames 12A and 12B linearly extend from the body portion 19 in the left-right direction. The main frames 12A and 12B are made of rod-shaped metal or synthetic resin. A main rotor 14A is rotatably disposed at the left end of the main frame 12A extending leftward. A pulley (not shown) is connected to the main rotor 14A, and a belt 20A is stretched between the pulley on the main rotor 14A side and the pulley on the engine 30 side (not shown). On the other hand, a main rotor 14B is rotatably arranged at the right end of the main frame 12B extending rightward. A pulley (not shown) is connected to the main rotor 14B, and a belt 20B is stretched between the pulley on the main rotor 14B side and the pulley on the engine 30 side (not shown). With such a configuration, the main rotor 14 is drivingly connected to the engine 30 . Therefore, since the main rotor 14 is directly rotated by the power generated from the engine 30, energy loss when transmitting energy from the engine 30 to the main rotor 14 can be reduced as compared with the series type.

The main rotor 14 has a function of generating an ascent force for floating the self-contained flight device 10 in the air. On the other hand, the sub-rotor 15 is mainly responsible for attitude control of the autonomous flying device 10 . For example, the sub-rotor 15 rotates appropriately to keep the position and orientation of the autonomous flying device 10 constant while the autonomous flying device 10 is hovering. Also, the sub-rotor 15 rotates to tilt the autonomous flight device 10 when the autonomous flight device 10 moves. Also, the main rotor 14A and the main rotor 14B rotate in opposite directions.

The subframes 13A and the like extend in the front-rear direction, and are made of rod-shaped metal or synthetic resin, like the main frames 12A and the like. The sub-frame 13A and the like extend from the middle portion of the main frame 12A and the like. A sub-rotor 15A is arranged at the front end of the sub-frame 13A, and the sub-rotor 15A is rotated by a motor 21A arranged below it. A sub-rotor 15B is arranged at the front end of the sub-frame 13B, and the sub-rotor 15B is rotated by a motor 21B arranged below it. A sub-rotor 15C is arranged at the rear end of the sub-frame 13C, and the sub-rotor 15C is rotated by a motor 21C arranged below it. A sub-rotor 15D is arranged at the rear end of the sub-frame 13D, and the sub-rotor 15D is rotated by a motor 21D arranged below it. Electric power generated by the generators 16A and 16B is supplied to the motors 21A, 21B, 21C and 21D. Wiring for supplying electric power to the motor 21A is routed inside the subframe 13A and the like.

Referring to FIG. 1B, length L10 of main frame 12A (the length from the center of main body 19 to the left end of main frame 12A) is longer than one blade of main rotor 14A. By doing so, the rotating main rotor 14A is prevented from coming into contact with the body portion 19. As shown in FIG. Furthermore, the length L10 of the main frame 12A is set sufficiently long so that the main rotor 14A does not come into contact with the sub-rotors 15A and 15C. The mainframe 12B has the same length as the mainframe 12A.

The length L20 of the sub-frame 13D is longer than the length of one blade of the sub-rotor 15D so that the sub-rotor 15D does not come into contact with the main body 19. As shown in FIG. Also, the length L20 of the sub-frame 13D (the length from the center of the main body 19 to the rear end of the sub-frame 13D) is set so as not to contact the main rotor 14B. Here, the other sub-rotors 15A, 15B, 15C have the same length as the sub-rotor 15D. Also, the lengths of the other subframes 13A, etc. are the same as the subframe 13D. Also, the length L10 of the main frame 12A is sufficiently longer than the length L20 of the sub-frame 13D.

The above-described main rotor 14 and sub-rotor 15 are arranged symmetrically with respect to a left-right symmetry line passing through the center of the main body 19 along the left-right direction. The main rotor 14 and the sub-rotor 15 described above are arranged symmetrically with respect to a longitudinal symmetry line that passes through the center of the main body 19 in the longitudinal direction. By symmetrically arranging the main rotor 14 and the sub-rotor 15 in this manner, the position and attitude of the autonomous flying device 10 in the air can be stabilized.

When the self-contained flight device 10 configured as described above flies, the main rotor 14 and the like and the sub-rotor 15A and the like rotate simultaneously. The thrust generated by the rotation of the main rotor 14 and the like causes the self-contained flight device 10 to float in the air, and the independent rotation of the sub-rotors 15A and the like controls the position and attitude of the self-contained flight device 10 in the air. . When the self-contained flight device 10 moves, attitude control is performed to tilt the self-contained flight device 10 by changing the rotation speed of the sub-rotor 15A and the like while rotating the main rotor 14 and the like at a predetermined speed. Such attitude control will be described later.

The connection configuration of the autonomous flying device 10 will be described with reference to the block diagram of FIG. The self-contained flight device 10 has an arithmetic control unit 31 for controlling its position and attitude in the air. The arithmetic control unit 31 comprises a CPU, RAM, ROM, etc., and controls the rotation of the motor 21A, etc. for driving the sub-rotor 15A, etc., based on instructions from various sensors, cameras, and operating devices (not shown). Here, the operation device is wirelessly or wiredly connected to the autonomous flight device 10, and enables the user to operate the position, altitude, movement direction, movement speed, etc. of the autonomous flight device 10. It is a so-called controller.

As described above, the self-contained flight device 10 can float in the air and move in a predetermined direction by rotating the main rotor 14 and the sub-rotor 15 with the driving energy generated by the engine 30 . Further, the position and orientation in the air are controlled by controlling the rotational speed of the motor 21A, etc., which rotates the sub-rotor 15. FIG.

The motor 21A and the like use the engine 30 as an energy source. A generator 16A, etc., an inverter 32 (power converter), a capacitor module 34, a driver 24A, etc. are interposed between the engine 30 and the motor 21A, etc. With such a configuration, the driving force generated by the engine 30 is converted into electric power, and the electric power rotates the motor 21A and the like at a predetermined rotational speed, thereby controlling the position and orientation of the autonomous flight device 10 and moving it.

The engine 30 is of a reciprocating type that uses gasoline or the like as fuel, as will be described later, and its driving force drives the generators 16A and 16B. Here, as described above, the engine 30 also drives the main rotor 14 . The engine 30 is controlled by an arithmetic and control unit 31 .

AC power generated from the generators 16A and 16B is supplied to the inverter 32 . In the inverter 32, the AC power is first converted into DC power by the converter circuit, and then the DC power is converted into AC power of a predetermined frequency by the inverter circuit. A portion of the power output from the inverter 32 is stored in the capacitor module 34 during hovering. The electric power stored in the capacitor module 34 is supplied to the motor 21A and the like when the autonomous flight device 10 changes its position and orientation. Since the capacitor module 34 can supply a large current to the load in a short time compared to a storage battery or the like, the rotation speed of the motor 21A or the like can be instantaneously increased, and the autonomous flight device 10 can be displaced at a high speed. can be made

Part of the power output from the inverter 32 is also supplied to the surplus power consumption circuit 33 . The surplus power consumption circuit 33 is a circuit for consuming the portion of the power converted by the inverter 32 that is not used by the motor 21A and the like. By providing the surplus power consumption circuit 33, the engine 30 and the inverter 32 can stably operate. The behavior of the inverter 32 is controlled by the arithmetic control unit 31 .

The drivers 24A, 24B, 24C, and 24D use the electric power generated by the inverter 32 to control the amount of current supplied to the motors 21A, 21B, 21C, and 21D, the direction of rotation, the timing of rotation, and the like. The behavior of the drivers 24A, 24B, 24C, and 24D is controlled by an arithmetic control unit 31. FIG.

In the self-contained flying device 10 configured as described above, the power supply system differs between the hovering state in which the device remains in a fixed position in the air and the moving state in which the device moves toward a predetermined position.

Specifically, in the hovering state, power is supplied to the generators 16A and 16B, the inverter 32, the driver 24A, etc., and the motor 21A, etc. in this order. Then, the arithmetic and control unit 31 controls the driver 24A and the like based on the outputs from various sensors so that the independent flying device 10 remains parallel to the ground and stays in a fixed position. The motor 21A is rotated at a predetermined number of revolutions. By doing so, the sub-rotor 15A and the like shown in FIG. 1 rotate at a predetermined speed, and the autonomous flight device 10 can stably hover.

On the other hand, in the moving state in which the autonomous flying device 10 is moved, first, the arithmetic and control unit 31 supplies power stored in the capacitor module 34 to the driver 24A and the like based on user instructions and the like via the controller. Therefore, in addition to power supplied from the inverter 32 , power is also supplied from the capacitor module 34 to the driver 24 and the like. For example, referring to FIG. 1, when the self-contained flying device 10 is moved forward, the arithmetic and control unit 31 controls the driver 24A and the like to direct the supplied power to the subrotors 15C and 15D. The power is supplied to the motors 21C and 21D to drive, and the rotation speed of the sub-rotors 15C and 15D is made faster than the rotation speed of the sub-rotors 15A and 15B.

By doing so, when the self-contained flight device 10 is viewed from the right side, the self-contained flight device 10 tilts so as to rotate slightly counterclockwise. When the main rotors 14A and 14B are rotated in such an inclined state, the resultant force of the lift generated by the main rotors 14A and 14B and the gravity acting on the self-contained flight device 10 acts forward. Therefore, the self-contained flying device 10 moves forward.

After the autonomous flight device 10 has moved to a predetermined location, the arithmetic and control unit 31 stops power supply from the capacitor module 34 to the drivers 24A and the like, and rotates the motors 21A and the like at substantially uniform speeds via the drivers 24A and the like. Let By doing so, the autonomous flying device 10 performs hovering again.

As described above, the self-contained flight device 10 according to the present embodiment has the main rotor 14 and the like rotated by the driving force of the engine 30, and the sub-rotor 15A and the like rotated by the motor 21 driven by the engine 30. It is of hybrid type. Therefore, compared with the above-described series type, the self-contained flying device 10 can achieve an energy consumption improvement rate of approximately 50%.

Next, the configuration of the engine 30 mounted on the self-contained flight device 10 having the configuration described above will be described with reference to FIGS. 3 to 5. FIG. In the self-contained flight device 10 of this embodiment, if the engine 30 generates a large vibration, the position and orientation of the self-contained flight device 10 in the air cannot be precisely controlled. It uses a vibrating type.

One form of the engine 30 will be described with reference to FIG. 3A is a cross-sectional view of the engine 30 viewed from the front, and FIG. 3B is a cross-sectional view of the engine 30 viewed from above. The engine 30 shown here has two engine sections (a first engine section 40 and a second engine section 41) arranged opposite to each other in the left-right direction.

3(A) and 3(B), the engine 30 includes a first engine section 40 arranged on the left side of the drawing and a second engine section 41 arranged on the right side. and

The first engine section 40 includes a first piston 43 that reciprocates in the left-right direction, a first crankshaft 42 that converts the reciprocating motion of the first piston 43 into rotational motion, the first piston 43 and the first crankshaft 42 . and a first connecting rod 44 rotatably connecting the .

The second engine section 41 includes a second piston 46 that reciprocates in the left-right direction, a second crankshaft 45 that converts the reciprocating motion of the second piston 46 into rotational motion, the second piston 46 and the second crankshaft 45 . and a second connecting rod 47 that rotatably connects the .

The upper end side of the first crankshaft 42 is connected to the pulley 22 and the generator 16A. Further, the upper end side of the second crankshaft 45 is connected to the pulley 23 and the generator 16B.

A combustion chamber 48 is shared by the first piston 43 of the first engine section 40 and the second piston 46 of the second engine section 41 . In other words, the first piston 43 and the second piston 46 reciprocate inside one communicating cylinder. Therefore, by simultaneously stroking the first engine section 40 and the first piston 43 toward the center portion, it is possible to achieve a high expansion ratio of the mixed gas in the combustion chamber 48 while reducing the stroke amount.

Although not shown here, the engine 30 has a voluminous space communicating with the combustion chamber 48, and a spark plug is arranged in this voluminous space. The combustion chamber 48 is formed with an intake port and an exhaust port (not shown). A mixture containing fuel such as gasoline is introduced into the combustion chamber 48 through the intake port, and the exhaust gas after combustion is discharged through the exhaust port. is exhausted from the combustion chamber to the outside.

Referring to FIG. 3A, engine 30 having the above configuration operates as follows. First, in the intake stroke, the first piston 43 and the second piston 46 move inside the cylinder 49 from the center toward the outside, thereby introducing a mixture of fuel and air into the cylinder 49. do. Next, in the compression stroke, the inertia of the rotating first crankshaft 42 and second crankshaft 45 pushes the first piston 43 and second piston 46 toward the center, and the air-fuel mixture is Compressed. Next, in the combustion stroke, a spark plug (not shown) ignites in the combustion chamber 48, causing the air-fuel mixture to burn inside the cylinder 49, thereby causing the first piston 43 and the second piston 46 to extruded to the end of the After that, in the exhaust stroke, the first piston 43 and the second piston 46 are pushed inward by the inertia of the rotating first crankshaft 42 and the second crankshaft 45, and the post-combustion gas existing inside the cylinder 49 is It is discharged outside.

In the engine 30 of this embodiment, the stroke can be divided by the two first pistons 43 and the second pistons 46 reciprocating inside one cylinder 49. compression ratio can be increased. In addition, since the first piston 43 and the second piston 46 face each other inside the cylinder 49, a cylinder head required in a general engine is not required, and the engine 30 is simple in construction and light in weight. there is Further, each member constituting the engine 30, that is, the first piston 43 and the second piston 46, the first crankshaft 42 and the second crankshaft 45, etc., are arranged facing each other and operate to face each other. ing. As a result, the vibration generated from each member of the engine 30 is canceled, and the vibration generated from the entire engine 30 to the outside can be reduced. Therefore, in this embodiment, by mounting the engine 30 having the structure described above, it is possible to reduce the size, weight, and vibration of the autonomous flight device 10 . In particular, due to the low vibration, it is possible to prevent adverse effects on arithmetic control devices such as attitude control and motor output control, and precision equipment such as GPS sensors. In addition, it is possible to prevent damage to the parcels to be delivered transported by the autonomous flight device 10 due to vibration.

Another form of the engine 30 will be described with reference to FIG. 4A is a side view of the engine 30 viewed from the front, and FIG. 4B is a top view of the engine 30. FIG.

4(A) and 4(B), here, the engine 30 consists of a left first engine section 60 and a right second engine section 61, and each engine section is individually operated. A cylinder is formed. This is different from the engine 30 shown in FIG.

The first engine section 60 includes a first cylinder 71, a first piston 70 that reciprocates inside the first cylinder 71, a first crankshaft 80 that converts the reciprocating motion of the first piston 70 into rotational motion, It has a first connecting rod 75 movably connecting the first piston 70 and the first crankshaft 80 , a first intake valve 64 and a first exhaust valve 62 .

The second engine section 61 includes a second cylinder 73, a second piston 72 that reciprocates inside the second cylinder 73, a second crankshaft 81 that converts the reciprocating motion of the second piston 72 into rotational motion, and a It has a second connecting rod 76 movably connecting the two pistons 72 and the second crankshaft 81 , a second intake valve 65 and a second exhaust valve 63 .

Here, the above-described first engine section 60 and second engine section 61 may be housed in an engine block integrally formed by casting. It may be housed separately in the engine block.

In engine 30, main constituent parts constituting first engine section 60 and second engine section 61 are arranged along the left-right direction. Specifically, the first cylinder 71, the first piston 70, the first crankshaft 80, and the first connecting rod 75 of the first engine section 60 are arranged along the left-right direction. Furthermore, the second cylinder 73, the second piston 72, the second crankshaft 81 and the second connecting rod 76 of the second engine section 61 are also arranged along the left-right direction. By arranging the constituent elements of each engine section along the left-right direction in this way, vibrations generated by the operation of each engine section are canceled out, and the damping effect can be improved.

Furthermore, the first engine section 60 and the second engine section 61 are arranged symmetrically in the left-right direction. With such a configuration as well, vibrations generated by the operation of each engine section are canceled with each other, and the damping effect can be improved.

4A and 4B, the first engine section 60 has a valve driving mechanism for controlling the operations of the first intake valve 64 and the second intake valve 65 described above. .

This valve drive mechanism has a crank pulley 82 , a cam pulley 85 , and a timing belt 74 stretched between the crank pulley 82 and the cam pulley 85 . The crank pulley 82 is connected to a portion of the first crankshaft 80 led out. A cam pulley 85 is attached to a camshaft 86 together with a first intake cam 84 that contacts the first intake valve 64 to control its forward/backward movement, and a second intake cam 87 that contacts the second intake valve 65 to control its forward/backward movement. Connected. For the first intake cam 84 and the second intake cam 87, the timing at which the first intake cam 84 presses the first intake valve 64 and the timing at which the second intake cam 87 presses the second intake valve 65 are the same. , are connected to the camshaft 86 with a phase difference.

Referring to FIG. 4A, the pulley 22 and the generator 16A are connected to the upper end side of the first crankshaft 80 of the first engine section 60, and the upper end side of the second crankshaft 81 of the second engine section 61 is connected. A pulley 23 and a generator 16B are connected to the .

A mechanism for driving the first exhaust valve 62 and the second exhaust valve 63 has a crank pulley 83 , a cam pulley 67 , and a timing belt 77 stretched between the crank pulley 82 and the cam pulley 85 . The crank pulley 83 is connected to a portion of the second crankshaft 81 led out. The cam pulley 67 is attached to the camshaft 66 together with a first exhaust cam 78 that contacts the first exhaust valve 62 to control its forward/backward movement and a second exhaust cam 79 that contacts the second exhaust valve 63 to control its forward/backward movement. Connected. The first exhaust cam 78 and the second exhaust cam 79 are arranged so that the timing at which the first exhaust cam 78 presses the first exhaust valve 62 and the timing at which the second exhaust cam 79 presses the second exhaust valve 63 are the same. , are connected to the camshaft 66 with a phase difference.

As shown in FIG. 4A, a reversing gear 68 is connected to the camshaft 66 to which the first exhaust cam 78 and the like are attached. Although not shown here, a reversing gear is also connected to the camshaft 86 (FIG. 4(B)). The reversing gear 68 of the camshaft 66 and the reversing gear of the camshaft 86 mesh. With such a configuration, a crankshaft reversal synchronization mechanism is configured in which the rotation direction of the first crankshaft 80 and the rotation direction of the second crankshaft 81 are reversed.

The operation of engine 30 shown in FIG. 4 is basically the same as that shown in FIG. That is, the first piston 70 and the second piston 72 move inward in the left-right direction at the same time to perform a compression stroke, etc., and further move outward in the left-right direction at the same time to perform a combustion stroke, etc. do. In addition, by configuring as described above, the flow path 88 and the flow path 89, which are intake and exhaust paths, are simplified, and intake and exhaust can be performed efficiently.

Another form of the engine 30 employed in the self-contained flight device 10 according to this embodiment will be described with reference to FIG. The engine 30 shown here has one piston 104 and extracts drive power from a crankshaft 100 and a balancer shaft 107 .

Specifically, the engine 30 rotates a cylinder 105, a piston 104 that reciprocates inside the cylinder 105, a crankshaft 100 that converts the reciprocating motion of the piston 104 into rotational motion, and the piston 104 and the crankshaft 100. and a connecting rod 103 for possible coupling. A crank gear 102, a pulley 22, and a generator 16A are attached to the upper end side of the crankshaft 100. As shown in FIG. A balance mass 101 is attached to the crankshaft 100 . By attaching the balance mass 101, the primary inertial force generated by the rotation of the crankshaft 100 can be reduced.

The balancer shaft 107 is arranged on the right side of the crankshaft 100 . The balancer shaft 107 is a so-called eccentric shaft. Rotation of the balancer shaft 107 together with the crankshaft 100 can reduce vibrations caused by the rotation of the crankshaft 100 . A balancer gear 109, a flywheel 110, a pulley 23, and a generator 16B are attached to the upper end side of the balancer shaft 107. As shown in FIG.

A balance mass 106 is attached to the balancer shaft 107 . The positional relationship between the balance mass 101 formed on the crankshaft 100 and the balance mass 106 formed on the balancer shaft 107 is symmetrical. Specifically, the positional relationship between the balance mass 101 and the balance mass 106 is line symmetrical with respect to a line of symmetry 111 defined perpendicular to the center between the rotation center of the crankshaft 100 and the rotation center of the balancer shaft 107. ing.

Although the balance mass 106 may be formed only on the balancer shaft 107 , here the balance mass 106 is formed on the balancer shaft 107 and the balancer gear 109 . In addition, the moment of inertia around the balancer shaft 107 including the balance mass 106 and the moment of inertia around the crankshaft 100 including the balance mass 101 are the same or substantially the same. By doing so, the vibration generated by the operation of the engine 30 can be further reduced.

A flywheel 110 can also be formed on the balancer shaft 107 here. In this case, by making the moment of inertia around the balancer shaft 107 including the flywheel 110 equal to the moment of inertia of the crankshaft 100, the damping effect can be further increased.

With reference to FIGS. 6 to 8, the power distribution ratio when the autonomous flying device 10 is tilted for movement will be described. FIG. 6 is a diagram for explaining the coordinate system used for the simulation. FIG. 7(A) is a side view showing the self-contained flight device 10 when tilted by 10 degrees, and FIG. 7(B) is a graph showing the temporal change of the output power in that case. FIG. 8(A) is a side view showing the self-contained flight device 10 when tilted at 35 degrees, and FIG. 8(B) is a graph showing temporal changes in output power in that case.

First, the equation of motion used to simulate the output of the autonomous flight device 10 will be described with reference to FIG. FIG. 6A is a graph showing a space-fixed coordinate system, and FIG. 6B is a graph showing a body-fixed coordinate system.

If a space-fixed coordinate system is taken as shown in FIG. 6A and a body-fixed coordinate system is taken as shown in FIG. can be done. where φ, θ, and ψ are Euler angles representing roll, pitch, and spin.

Also, the translational motion of the center of gravity { _XG , _YG , _ZG } ^T of the self-contained flight device 10 is described by Equation 2 below in a space-fixed coordinate system. Here, m is the airframe weight of the self-contained flight device 10, g is the gravitational acceleration, and T is the thrust generated by the main rotor 14A and the like and the sub-rotor 15A and the like.

Furthermore, the rotational motion around the center of gravity of the self-contained flight device 10 is described by the following Equation 3 in the body-fixed coordinate system. where I _XX , I _YY , I _ZZ are the moment of inertia of the airframe about each axis, {W ₁ , W ₂ , W ₃ } ^T is the angular velocity vector, and {τ _φ , τ _θ , τ _ψ } ^T represents the torque around each axis produced by the attitude control rotor.

The motion of the self-contained flying device 10 was simulated based on the above equations, and the following results were obtained.

In this simulation, we verified the difference in the power distribution ratio between hovering and attitude control. Here, the time of attitude control is when the autonomous flying device 10 is tilted by, for example, 10 degrees in order to move the autonomous flying device 10 in the air. The power distribution ratio is the ratio between the power generated by rotating the main rotor 14A and the like and the power generated by rotating the sub-rotor 15A and the like.

When the self-contained flight device 10 is hovering, the main rotor 14A and the like generate a thrust to levitate the device body, while the sub-rotor 15A and the like keep the device body at a predetermined position and maintain a horizontal state. Rotate. Therefore, the output of the main rotor 14 and the like is much larger than the output of the sub-rotor 15A and the like. For example, the power output by the main rotor 14 and the like is 3.04W, and the power output by the sub-rotor 15A and the like is 0.34W. The output distribution ratio between the main rotor 14 and the like and the sub-rotor 15A and the like is, for example, 90%:10%.

Since the main rotor 14 etc. and the output shaft of the engine 30 are connected for driving, the energy loss in the path through which energy is transmitted from the engine 30 to the main rotor 14 etc. is very small. That is, the energy efficiency of the path through which energy is transmitted from the engine 30 to the main rotor 14 and the like is very high. On the other hand, the sub-rotor 15A, etc., as shown in FIG. and low. Therefore, by increasing the output distribution ratio of the main rotor 14 and the like during hovering, the energy generated by the engine 30 can be effectively used to float the self-contained flight device 10 .

On the other hand, during attitude control, the sub-rotor 15A and the like are rotated at high speed in order to tilt the self-contained flight device 10 . Therefore, the ratio of the energy supplied to the sub-rotor 15A and the like is increased compared to when hovering. Further, as the tilt angle of the self-contained flight device 10 increases, the sub-rotor 15A and the like need to be rotated at a higher speed, so the ratio of the energy supplied to the sub-rotor 15A and the like increases.

With reference to FIG. 7, a case in which the self-contained flying device 10 is tilted by 10 degrees during attitude control will be described. FIG. 7(A) is a side view showing a state in which the self-contained flight device 10 is tilted by 10 degrees, and FIG. 7(B) is a graph showing temporal changes in the power generated by each rotor. Here, the power is the thrust force generated by the rotation of each rotor.

Referring to FIG. 7A, during attitude control, arithmetic and control unit 31 rotates sub-rotors 15C and 15D faster than sub-rotors 15A and 15B, thereby acting on the rear portion of autonomous flight device 10. The lift force is made greater than the lift force acting on its forward portion, causing the self-contained flight device 10 to tilt counterclockwise. Here, the sub-rotor 15A and the like are rotated so that the inclination angle θ of the self-contained flight device 10 is 10 degrees.

The horizontal axis of the graph shown in FIG. 7B is time, and the vertical axis is power generated from each rotor. Here, the dashed line indicates the power of the sub-rotor 15A and the like, the dotted line indicates the power of the main rotor 14 and the like, and the solid line indicates the total value of the power of the sub-rotor 15A and the like and the power of the main rotor 14 and the like.

Referring to this figure, at time T1, the sub-rotors 15C and 15D are rotated at a higher speed than the sub-rotors 15A and 15B, so that the power of the sub-rotors 15A and the like reaches a maximum value (approximately 0.5 kW). By doing so, the inclination angle of the self-contained flight device 10 is set to 10 degrees as described above. In this state, the rotational speeds of the sub-rotors 15C and 15D are made approximately equal to those of the sub-rotors 15A and 15B, so that the thrust of the main rotor 14 and the like causes the self-contained flight device 10 to move forward. Further, in this embodiment, the power supplied from the capacitor module 34 shown in FIG. 2 can immediately increase the rotation speed of the sub-rotors 15C and 15D.

At time T2, since the autonomous flying device 10 reaches a predetermined speed, the rotational speeds of the subrotors 15A and 15B are set higher than those of the subrotors 15C and 15D in order to bring the autonomous flying device 10 into a horizontal state. . Also at this time, the power of the sub-rotor 15A and the like is relatively large, but is small compared to the power at time T1.

From time T1 to time T2, the self-contained flight device 10 is tilted to generate acceleration. After time T2, the autonomous flying device 10 moves at a constant speed.

During the attitude control of the self-contained flight device 10, the output of the main rotor 14, etc. basically does not fluctuate and is approximately 3 kw. Also, at this time, the rotation speed of the engine 30 may be constant, or may be increased as necessary.

When the self-contained flight device 10 is tilted by 10 degrees as described above, the maximum power of the sub-rotor 15A etc. is about 0.6 kw, and the power of the main rotor 14 etc. is about 3.0 kw. Therefore, the output distribution ratio between the main rotor 14 and the like and the sub-rotor 15A and the like is 86%:14%.

A case in which the self-contained flight device 10 is tilted by 35 degrees will be described with reference to FIG. FIG. 8(A) is a side view showing the self-contained flight device 10 tilted at 35 degrees, and FIG. 8(B) is a graph showing changes in power over time in this case. Here, the control method for tilting the self-contained flying device 10 to move is the same as the case shown in FIG. By increasing the inclination angle θ of the self-contained flight device 10 in this manner, the self-contained flight device 10 can be moved at higher speed.

Referring to FIG. 8(B), when the self-contained flight device 10 is tilted by 35 degrees, it is necessary to rotate the subrotors 15C and 15D at a higher speed. Therefore, the maximum value of the sub-rotor 15A, etc. at time T3 is about 1.3 kw. Also, at time T4, the power of the sub-rotor 15A and the like increases again so that the self-contained flight device 10 is placed in a horizontal state. Here, from time T3 to time T4, the self-contained flight device 10 is tilted to generate acceleration, and at time T4, the self-contained flight device 10 is placed in a horizontal state to reduce the acceleration to zero. After time T4, the autonomous flying device 10 moves at a constant speed. Here, since the self-contained flight device 10 is greatly inclined, the acceleration acting on the self-contained flight device 10 can be increased and the self-contained flight device 10 can be moved at high speed.

As described above, during attitude control of the self-contained flight device 10, the output of the main rotor 14 and the like basically does not fluctuate and is approximately 3 kw. Also, at this time, the rotation speed of the engine 30 may be constant.

Therefore, when the self-contained flight device 10 is moved by tilting it by 35 degrees, the output distribution ratio between the main rotor 14 and the like and the sub-rotor 15A and the like is, for example, 70%:30%. That is, the output of the sub-rotor 15A and the like is increased compared to the case where the self-contained flight device 10 is tilted by 10 degrees.

In this embodiment, when the attitude of the autonomous flight device 10 is changed, the output distribution ratio of the subrotor 15A and the like is increased compared to when hovering. By doing so, the sub-rotor 15A and the like are rotated at high speed while the self-contained flight device 10 is kept floating by the thrust of the main rotor 14 and the like, thereby immediately tilting and moving the self-contained flight device 10. can be made

Further, when the attitude of the autonomous flight device 10 is changed, it is preferable that the output distribution ratio to the sub-rotor 15A and the like is 10% or more and 30% or less when the output of the sub-rotor 15A or the like is maximized. By setting the output distribution ratio to 10% or more, the sub-rotor can obtain sufficient rotational force, and the self-contained flight device 10 can be suitably tilted and moved in the air. Also, by setting the output distribution ratio to 30% or less, the attitude of the autonomous flying device 10 in the air can be stabilized.

In general, for attitude control of a multi-rotor self-contained flight device, an output response on the order of 100 msec is required, but an engine-driven self-contained flight device does not have a sufficient output response speed, so an accurate attitude is required. Control was not easy. On the other hand, in the self-contained flight device 10 according to the present embodiment, the attitude control of the self-contained flight device 10 is performed by electronically controlling the number of revolutions of the motor 21A, etc., which rotates the subrotor 15A, etc. output response becomes possible, and the attitude control of the self-contained flying device 10 can be performed accurately.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above embodiments.

Referring to FIG. 2, self-contained flight device 10 may be provided with a storage battery. That is, part of the electric power generated from the generator 16A or the like may be charged in the storage battery, and the electric power discharged from the storage battery may be used to rotate the motor 21A or the like.

Referring to FIG. 1, the driving force of engine 30 is transmitted to main rotor 14 and the like via belt 20A and the like. may be transmitted to

The invention that can be grasped from the above-described embodiment will be described below together with the effects that the invention produces.

An engine-mounted self-contained flight device according to the present invention comprises: a main rotor that applies a main thrust to an airframe; a sub-rotor that controls the attitude of the airframe; an engine that generates energy for rotating the main rotor and the sub-rotor; and an arithmetic control unit for controlling rotation of a sub-rotor, wherein the main rotor rotates by being drivingly connected to the engine, and the sub-rotor generates electric power from a generator driven by the engine. It is characterized in that the arithmetic and control unit increases the output distribution ratio of the sub-rotor when performing attitude control for tilting the fuselage than when hovering. Therefore, when performing attitude control for tilting the airframe in order to move the engine-mounted self-contained flight device in the air, the airframe can be favorably tilted and moved by increasing the output distribution ratio of the sub-rotor.

Further, in the engine-mounted self-contained flight device of the present invention, the arithmetic and control unit is characterized in that, when performing the attitude control, the output distribution ratio to the sub-rotor is 10% or more and 30% or less. Therefore, by setting the output distribution ratio to the sub-rotor to 10% or more when performing attitude control, the sub-rotor can obtain a sufficient rotational force, and the airframe can be tilted and moved appropriately in the air. Also, by setting the output distribution ratio to the sub-rotor to 30% or less, the attitude of the aircraft in the air can be stabilized.

Further, the engine-mounted self-contained flight device of the present invention further comprises a power converter that converts the power generated from the generator, and a capacitor that stores the power output from the power converter, The arithmetic and control device is characterized in that when the hovering is performed, the capacitor is charged, and when the attitude control is performed, the electric power discharged by the capacitor is supplied to the motor. Therefore, when performing attitude control, by supplying the electric power discharged by the capacitor to the motor, the output of the sub-rotor can be rapidly increased, and the engine-equipped self-contained flight device can be moved at high speed in the air. .

Further, in the engine-mounted self-contained flight device of the present invention, the number of revolutions of the engine is substantially the same during hovering and during attitude control. Therefore, when performing attitude control, the total energy required by the main rotor and sub-rotor is greater than that required during hovering, but in the present invention, the energy is supplemented by the electrical energy discharged from the capacitor. Therefore, since there is no need to increase the rotation speed of the engine for attitude control, the attitude control can be simplified.

Further, in the engine-mounted self-contained flight device of the present invention, the engine and the main rotor are drivingly connected via a belt. Therefore, by drivingly connecting the engine and the main rotor with the belt, it is possible to easily drively connect the engine and the main rotor even if the distance between the engine and the main rotor is long. Furthermore, since the belt is lighter than other power transmission means such as gears, the adoption of the belt can reduce the weight of the engine-mounted self-contained flying device.

Further, in the engine-mounted self-contained flight device of the present invention, the engine includes a first engine section having a reciprocating first piston, and a second engine section having a second piston reciprocating while facing the first piston. and an engine section. Therefore, the reciprocating motion of the opposed pistons in the first engine section and the second engine section cancels out the vibration caused by the reciprocating motion, and the vibration caused by the operation of the engine is extremely reduced. be able to.

Further, in the engine-mounted self-contained flight device of the present invention, the first piston and the second piston reciprocate inside a communicating cylinder. Therefore, since the first piston and the second piston reciprocate in the same cylinder, the vibration generated from the engine can be suppressed, and the structure of the engine can be simplified.

Further, in the engine-mounted self-contained flight device of the present invention, the first piston reciprocates inside the first cylinder, and the second piston moves inside the second cylinder formed separately from the first cylinder. It is characterized by reciprocating motion. Therefore, by having separate cylinders for the first engine section and the second engine section, the first engine section and the second engine section can be prepared separately, and the manufacturing cost can be reduced. Furthermore, the intake and exhaust paths of the first and second cylinders can be shaped to suit intake and exhaust.

Further, in the engine-mounted self-contained flight device of the present invention, the sub-rotor is attached to the tip side of a sub-arm extending outward from the location where the engine is arranged, and the main rotor is attached to the outside from the location where the engine is arranged. and attached to the tip side of a main arm that is longer than the sub-arm. Therefore, by lengthening the main arm to which the main rotor is attached, each rotor constituting the main rotor can be lengthened, and the payload can be further increased. Also, by shortening the sub-arm to which the sub-rotor is attached, it is possible to precisely perform attitude control and the like by changing the rotation speed of the sub-rotor.

Further, in the engine-mounted self-contained flight device of the present invention, the main rotor includes an engine-side pulley attached to a shaft extending outside from the crankshaft of the engine, and a rotor-side pulley attached to the main rotor. and a belt hung between the engine-side pulley and the rotor-side pulley. Therefore, the driving force generated from the engine can be transmitted to the main rotor with a relatively simple configuration.

Further, in the engine-mounted self-contained flight device of the present invention, the direction in which the first engine section and the second engine section constituting the engine are aligned is defined as the first direction, and the direction perpendicular to the first direction is defined as the second direction. In this case, the main rotor includes a first main rotor driven by the first engine section and arranged outside along the first direction, and a first main rotor driven by the second engine section and arranged outside the first main rotor in the first direction. a second main rotor leveled at a position facing the rotor, the sub-rotors being arranged on the side of the first main rotor on the outer side along the second direction; the second sub-rotor arranged at a position facing the first sub-rotor along two directions; a third sub-rotor arranged outside along the second direction on the side of the second main rotor; and the fourth sub-rotor disposed at a position facing the third sub-rotor in two directions. Therefore, by having the first main rotor and the second main rotor at both ends along the first direction and having four sub-rotors, the payload is increased by the first main rotor and the second main rotor, and the A single sub-rotor can precisely control the attitude of the entire airframe.

Further, in the engine-mounted self-contained flight device of the present invention, the engine has a crankshaft having a first balance mass formed thereon, and a second balance mass formed at a symmetrical position with respect to the first balance mass. a balancer shaft, and the driving force of the crankshaft and the balancer shaft rotates the main rotor. Therefore, each rotor can be driven by the power extracted from the crankshaft and the balancer shaft without having a plurality of engine parts.

10 Independent flight device 11 Frames 12, 12A, 12B Main frames 13, 13A, 13B, 13C, 13D Subframes 14, 14A, 14B Main rotors 15, 15A, 15B, 15C, 15D Subrotors 16, 16A, 16B Generator 17 Casing 18 Skid 19 Body 20, 20A, 20B Belts 21, 21A, 21B, 21C, 21D Motor 22 Pulley 23 Pulleys 24, 24A, 24B, 24C, 24D Driver 30 Engine 31 Arithmetic control unit 32 Inverter 33 Surplus power consumption circuit 34 Capacitor module 40 First engine part 41 Second engine part 42 First crankshaft 43 First piston 44 First connecting rod 45 Second crankshaft 46 Second piston 47 Second connecting rod 48 Combustion chamber 49 Cylinder 60 First engine part 61 Second engine section 62 First exhaust valve 63 Second exhaust valve 64 First intake valve 65 Second intake valve 66 Camshaft 67 Cam pulley 68 Reverse gear 70 First piston 71 First cylinder 72 Second piston 73 Second cylinder 74 Timing belt 75 First connecting rod 76 Second connecting rod 77 Timing belt 78 First exhaust cam 79 Second exhaust cam 80 First crankshaft 81 Second crankshaft 82 Crank pulley 83 Crank pulley 84 First intake cam 85 Cam pulley 86 Cam Shaft 87 Second intake cam 88 Channel 89 Channel 100 Crankshaft 101 Balance mass 102 Crank gear 103 Connecting rod 104 Piston 105 Cylinder 106 Balance mass 107 Balancer shaft 109 Balancer gear 110 Flywheel 111 Line of symmetry

Claims (2)

A main rotor that provides a main thrust to the airframe, a sub-rotor that controls the attitude of the airframe, an engine that generates energy for rotating the main rotor, an arithmetic and control unit that controls the rotation of the sub-rotor, and a generator. , a power converter, a motor, and a surplus power consumption circuit;
The main rotor rotates by being drivingly connected to the engine,
The power converter converts the power generated by the generator,
The sub-rotor is rotated by the motor driven by the electric power converted by the power converter ,
A flight device characterized in that, when the flight device is floating in the air, the surplus power consumption circuit consumes part of the power generated from the generator and converted by the power converter. . A main rotor that provides a main thrust to the airframe, a sub-rotor that controls the attitude of the airframe, an engine that generates energy for rotating the main rotor, an arithmetic and control unit that controls the rotation of the sub-rotor, and a generator. , a power converter, a motor, and a surplus power consumption circuit;
The main rotor rotates by being drivingly connected to the engine,
The power converter converts the power generated by the generator,
The sub-rotor is rotated by the motor driven by the electric power converted by the power converter ,
When the flying device is floating in the air, the surplus power consumption circuit consumes part of the power generated from the generator and converted by the power converter , thereby A flight device , wherein the power converter can stably operate .

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