JP5713231B2 - Flying object - Google Patents

Description

  The present invention relates to an aircraft that flies by receiving lift from a rotating rotor.

  Conventionally, there is a technique related to a so-called unmanned aerial vehicle (UAV) (see, for example, Patent Document 1 and Patent Document 2). Patent Document 1 and Patent Document 2 are particularly supported on the same axis to obtain lift. This is a technique related to a double-reversed rotor type aircraft having two rotors rotating in opposite directions. In a double-reversed rotor type flying body, the rotation of one rotor is used to cancel the torque around the rotation axis generated as a reaction force caused by the rotation of the other rotor.

JP 2005-319970 A JP 2008-094278 A

  According to the flying object disclosed in Patent Document 1 and Patent Document 2, the movement in the vertical direction is possible in a state where the rotation axis direction of the rotor is the vertical direction. However, the flying object as disclosed in Patent Document 1 and Patent Document 2 has a large number of parts and a complicated structure. In particular, in the case of the double reversing rotor type configuration, as described above, a configuration for canceling the torque as a reaction force due to the rotation of the rotor is required.

  In this regard, there is a single-rotor type helicopter mainly composed of a single rotor disposed at the top of the fuselage. However, even in a single rotor type helicopter, for example, a configuration for canceling torque as a reaction of rotation of the main rotor, such as a tail rotor provided at the rear of the aircraft, is required.

  In this way, in a flying object that moves by obtaining lift by the rotation of the rotor, the torque as a reaction of the rotation of the rotor is canceled to suppress the rotation of the aircraft itself, and the position of the aircraft Controllability and maneuverability are ensured. For this reason, the structure of the airframe is complicated and large. If the structure of the fuselage is complex and large, it tends to cause many failures and maintenance becomes difficult.

  The present invention has been made in view of the above problems, and the problem to be solved is to control the position of the airframe without canceling the torque as a reaction of the rotation of the rotor to obtain lift. Another object of the present invention is to provide a flying object that can easily be realized with a simple structure, a small size, and a light weight configuration, has few failures and is easy to maintain, and can be manufactured at low cost.

The flying body of the present invention includes a rotor that generates lift by rotating, a driving source that rotates the rotor, the rotor and the driving source, and a reaction force generated by the rotation of the rotor. By rotating in the direction opposite to the rotation direction of the rotor and flying by the lift obtained by the rotation of the rotor, the aircraft is movably provided with respect to the aircraft, and the aircraft is rotated by the reaction force. By changing the flow of the airflow that receives resistance, the movable body is tilted in a predetermined tilt direction in which the rotation axis of the rotor is tilted, and the azimuth that the aircraft is facing is detected. an azimuth detecting means, provided in the machine body, based on the direction detected by said azimuth detection means, the direction of the machine body which is rotated by the reaction force travel of the aircraft At the timing when the timing toward a predetermined instruction orientation indicated by, and the body faces the direction opposite the indicated direction, such that the movable blade is tilted toward the indication orientation relative to said body, said The movement of the aircraft is controlled by controlling the operation of the movable wing in synchronization with the rotation of the aircraft, and periodically moving the movable wing so that the aircraft tilts with the tilt direction corresponding to the indicated direction. And a controller for controlling.

  In addition, the flying object of the present invention preferably includes a GPS sensor that receives a signal from a GPS satellite, and the controller detects a current position of the aircraft based on the signal received by the GPS sensor, The movement of the aircraft is controlled using the current position.

  In addition, the flying body of the present invention preferably includes a receiver that receives a radio signal for remotely operating at least one of the drive source and the movable wing, and the controller receives the radio signal received by the receiver. Based on a radio signal, the operation of at least one of the drive source and the movable blade is controlled.

  The aircraft of the present invention preferably includes altitude detection means for detecting the altitude of the airframe, and the controller detects a target value for the altitude of the airframe inputted in advance and the altitude detection means. The operation of the drive source is controlled so as to maintain the altitude of the airframe at the target value by performing feedback control by comparison with the detected value.

  In addition, the flying body of the present invention preferably includes height position detection means for detecting a distance of the aircraft relative to the ground surface, and the controller is preliminarily input with the distance detected by the height position detection means. When the predetermined distance is reached, the operation of the drive source is controlled so that the airframe will hover.

  According to the present invention, it is possible to control the position of the airframe without canceling the torque as a reaction of the rotation of the rotor for obtaining lift, and it is possible to easily realize a simple structure, a small size and a light weight configuration. Can be produced at low cost with few failures and easy maintenance.

The figure which shows the structure of the flying body which concerns on one Embodiment of this invention. The block diagram which shows the structure of the flying body which concerns on one Embodiment of this invention. Explanatory drawing explaining operation | movement of the flying body which concerns on one Embodiment of this invention. Explanatory drawing explaining operation | movement of the flying body which concerns on one Embodiment of this invention. Explanatory drawing explaining operation | movement of the flying body which concerns on one Embodiment of this invention. Explanatory drawing which shows an example of the navigation control of the flying body which concerns on one Embodiment of this invention.

  The present invention specializes the movement of the aircraft in vertical ascending / descending movements and enables lateral movement (horizontal direction). The present invention is a vehicle equipped with a rotor for obtaining lift, and makes use of torque as a reaction force of rotation of the rotor, which is offset by some configuration in a normal aircraft, and autonomously while rotating the aircraft by that torque. The structure which sails to is realized.

  The flying object of the present invention moves the aircraft vertically up and down by rotation control of the rotor to obtain lift. Further, the flying body of the present invention changes the airflow around the airframe that is rotated by the reaction torque of the rotor while flying by receiving the lift from the rotation of the rotor, and tilts the airframe by tilting the airframe. It produces a horizontal component of lift due to and moves laterally. For this reason, the flying body of the present invention operates the movable wings periodically in synchronization with the rotation of the airframe, thereby intermittently flowing the airflow that tilts the airframe according to the direction of travel of the airframe in the lateral direction. To cause.

  With such a configuration, the flying body of the present invention realizes an autonomously stable airframe structure. This airframe structure has a simple principle and a mechanical control mechanism, so that there are fewer failures and easy maintenance. It becomes.

  The flying object of the present invention can be used for various applications. For example, it can be used as a weather observation apparatus by mounting a sensor for weather observation or the like. In addition, by installing a camera, it can be used as an imaging device that performs imaging from above. The flying object of the present invention can also be applied as a hobby toy. Moreover, the flying body of the present invention can be used as a repeater for wireless communication by mounting a wireless communication device. Embodiments of the present invention will be described below.

  The structure of the flying object 1 of this embodiment is demonstrated using FIG.1 and FIG.2. As shown in FIG. 1, the flying object 1 is configured as a single-propeller type autonomous flying object having one propeller 3 provided on one end side of the airframe 2. The flying object 1 includes an airframe 2, a propeller 3, a motor 4, a tail 5, a geomagnetic sensor 6, and a microcomputer 7.

  The airframe 2 is comprised by the plate-shaped member of a substantially isosceles triangle shape. The machine body 2 holds a propeller 3 and a motor 4.

  The propeller 3 functions as a rotor that generates lift by rotating. In the present embodiment, the propeller 3 includes two blades 3a for obtaining lift and a hub 3b that supports these blades 3a. The two blades 3a are provided at symmetrical positions with respect to the position of the rotation axis of the propeller 3.

  The propeller 3 is disposed on the bottom side (upper side in FIG. 1) of the outer shape of the isosceles triangle with respect to the airframe 2. The propeller 3 has a direction of the rotation axis that is substantially parallel to the plate surface of the body 2 and is substantially perpendicular to the base of the substantially isosceles triangular shape of the body 2, and the rotation axis is substantially the same as that of the body 2. It is provided so as to be positioned substantially at the center of the bottom of the equilateral triangular shape. The propeller 3 is rotated by the motor 4.

  The motor 4 functions as a drive source that rotates the propeller 3. The motor 4 has a drive shaft 4 a and connects the drive shaft 4 a to the hub 3 b of the propeller 3 to transmit a rotational driving force to the propeller 3. The motor 4 is, for example, a relatively small brushless motor. The motor 4 is driven by power supplied from the battery 10. The battery 10 is held at a predetermined position of the machine body 2.

  As shown in FIG. 1, the motor 4 is provided in a state of being supported by a support pillar 11 included in the machine body 2. The support pillar 11 is a linear ridge portion provided along the direction of the rotation axis of the propeller 3 in the airframe 2. The support pillar 11 is configured, for example, by attaching a rod-shaped member to the body 2. The motor 4 is fixed to the end portion on the side where the propeller 3 is located with respect to the support column 11 via a predetermined support member or the like.

  As described above, the motor 4 is held by the body 2 while being supported by the support pillars 11 provided in the body 2. Further, the propeller 3 connected to the motor 4 is held by the machine body 2 via the motor 4 fixed to the machine body 2.

  As shown in FIG. 2, the motor 4 is controlled by the microcomputer 7 via the motor amplifier 12. The motor amplifier 12 receives a signal from the microcomputer 7, senses the voltage of the battery 10, and adjusts the voltage supplied to the motor 4. Therefore, the battery 10 is connected to the motor amplifier 12 and supplies power to the motor 4 via the motor amplifier 12.

  As described above, the flying object 1 including the airframe 2, the propeller 3 held by the airframe 2, and the motor 4 rises by the lift generated by the rotation of the propeller 3 driven by the motor 4 and flies. For this reason, the flying object 1 flies in a posture in which the side on which the propeller 3 is arranged with respect to the airframe 2, that is, the bottom side in the substantially isosceles triangular shape of the airframe 2 is the upper side.

  In the following description, in the flying object 1, the side (upper side in FIG. 1) on which the propeller 3 is disposed with respect to the airframe 2 is defined as the upper side, and the opposite side (lower side in the same figure) is defined as the lower side. Further, in the flying object 1, regarding the airframe 2 configured in a plate shape, the side where the support pillar 11 is provided (the side shown in FIG. 1) is the front side, and the opposite side is the back side.

  In the flying body 1, as described above, the airframe 2 that holds the propeller 3 and the motor 4 flies while rotating in the opposite direction to the propeller 3 as the propeller 3 rotates. That is, the airframe 2 receives a reaction force caused by the rotation of the propeller 3 and rotates in a direction opposite to the rotation direction of the propeller 3 and also flies by a lift obtained by the rotation of the propeller 3.

  Specifically, as shown in FIG. 1, when the propeller 3 rotates in a predetermined direction (see arrow A <b> 1) to give lift to the airframe 2, the rotation axis of the propeller 3 is a reaction of the rotation of the propeller 3. Around the torque is generated. The torque as a reaction of the rotation of the propeller 3 acts as a force for rotating the airframe 2 around the rotation axis of the propeller 3 in the direction opposite to the propeller 3 (see arrow A2).

  The flying object 1 gains lift by the rotation of the propeller 3 and flies while rotating the airframe 2 in the opposite direction to the propeller 3 by the torque as a reaction of the rotation of the propeller 3. The flying object 1 flying in this way flies in a posture in which the propeller 3 side is on the upper side as described above. The airframe 2 rotates at a rotation speed of, for example, about 1/10 to 1/100 of the rotation speed (rotation speed) of the propeller 3.

  The airframe 2 functions as a resistance body that maintains the attitude of the aircraft 1 by receiving air resistance against the reaction force caused by the rotation of the propeller 3 while rotating in the direction opposite to the propeller 3. In the present embodiment, the plate-shaped airframe 2 rotates while receiving air resistance mainly by the plate surfaces on both sides due to the reaction force of the rotating propeller 3, and the attitude of the flying vehicle 1 with the propeller 3 side on the upper side as described above. Hold on.

  As described above, the flying object 1 gains lift by the rotation of the propeller 3, so that the airframe 2 is rotated by the reaction of the rotation of the propeller 3, and autonomously stable, vertically moving up and down, and stopped. Fly in the state (hovering). In the flying object 1 in a state of flying by the rotation of the propeller 3, the lower part of the propeller 3 including the airframe 2 and the motor 4 is suspended from the part of the propeller 3 by its own weight, and the posture is Stabilize.

  In the flying state, the flying body 1 is such that the plate surface of the flying body 2 is substantially along the vertical direction due to the air resistance received by the reaction force of the rotating propeller 3 and the weight of the flying body 2 itself. Get autonomous stability with posture. For this reason, the airframe 2 takes into account the air resistance received by rotating by the reaction torque of the propeller 3 in relation to the size of the propeller 3 and the moment generated by the rotation of the propeller 3, etc. It is configured to have a shape, size, weight and the like that can obtain a stable posture during flight 1.

  Specifically, in the airframe 2, when the area and weight that receive the air resistance that generates resistance against the reaction force caused by the rotation of the propeller 3 are not sufficiently secured, the airframe 2 obtains the lift of the propeller 3 and floats. Can not do. Conversely, when the size and weight of the airframe 2 are too large compared to the propeller 3, the airframe 2 cannot float due to the lift of the propeller 3 due to the air resistance received by the airframe 2, the weight of the airframe 2, and the like. Therefore, the shape, size, weight, etc. of the airframe 2 are set in consideration of the balance in relation to the propeller 3 so that the airframe 2 can lift with the propeller 3 and fly in a stable posture. The

  Further, the smaller the resistance force against the reaction force caused by the rotation of the propeller 3 is, the faster the rotational speed of the airframe 2 is. Conversely, the greater the resistance force is, the slower the rotational speed of the airframe 2 is. Although details will be described later, the flying object 1 performs control in synchronization with the rotation of the airframe 2 with respect to the operation of the tail 5. Therefore, in the control synchronized with the rotation of the airframe 2 due to the reaction force of the propeller 3, the rotational speed of the airframe 2 is taken into consideration so that the rotational speed of the airframe 2 is controllable, and the shape of the airframe 2 is Is set.

  From the viewpoint of flying in an autonomous and stable posture in the relationship between the aircraft 2 and the propeller 3 that rotate in opposite directions in the aircraft 1, the aircraft 2 is substantially isosceles triangular as in the present embodiment. A shape or a substantially equilateral triangular shape is preferable. The flying body 1 is lifted by the rotation of the propeller 3 provided on the bottom side, with the apex angle side (one corner side in the case of a substantially equilateral triangle) as the lower side and the base side as the upper side. To fly.

  However, the configuration of the aircraft 2 is not particularly limited as long as the aircraft 1 can fly in a state where the attitude of the aircraft 1 is stable in relation to the propeller 3. Further, the number, shape, etc. of the blades 3a constituting the propeller 3 are also particularly limited as long as the flying object 1 can fly in a state in which the attitude of the flying object 1 is stabilized in relation to the airframe 2. It is not a thing. That is, the airframe 2 and the propeller 3 are configured in consideration of the balance between each other so that the flying body 1 can fly in a state where the attitude of the aircraft 1 is stabilized by the lift obtained by the propeller 3.

  The tail 5 is configured to move the flying vehicle 1 flying by obtaining lift by the rotation of the propeller 3 in the lateral direction (horizontal direction). While the flying object 1 flies by receiving the lift from the rotation of the propeller 3, the airflow around the rotating body 2 is changed by the reaction torque of the propeller 3 by the operation of the tail 5, and the aircraft 2 is tilted. Then, a horizontal component of the lift force generated by the propeller 3 is generated to move in the lateral direction.

  The tail 5 is provided so as to be movable with respect to the body 2. As shown in FIG. 1, in the flying body 1 of the present embodiment, the tail 5 is constituted by a plate-like member having an isosceles triangle shape, and the apex side that is the lower end side of the substantially isosceles triangle-shaped airframe 2. Is provided.

  Specifically, the tail wing 5 has substantially the same thickness as that of the airframe 2 and constitutes a substantially isosceles triangular outer shape integrally with the airframe 2 (see FIG. 1). In other words, the portion forming the apex in the substantially isosceles triangular outer shape of the airframe 2 is constituted by the isosceles triangular tail wing 5. That is, in the flying body 1 of the present embodiment, the airframe 2 having a substantially isosceles triangular shape has the tail 5 as a portion constituting the lower end portion serving as the apex angle portion in the outer shape. Therefore, the tail wing 5 is arranged on the lower side of the airframe 2 with the bottom side of the isosceles triangular shape facing the lower end side of the airframe 2 with respect to the airframe 2.

  As shown in FIG. 1, the tail wing 5 is movably connected to the airframe 2 by the connecting portion 13 in a state of being arranged below the airframe 2 as described above. The connecting portion 13 connects the lower end side of the airframe 2 and the upper end side of the tail 5 that face each other.

  The connecting portion 13 connects the tail 5 to the body 2 so that the tail 5 tilts with respect to the body 2 on both the front side and the back side of the body 2 within a predetermined angle range. Therefore, the integral isosceles triangular plate-like body constituted by the airframe 2 and the tail 5 is formed such that the tail 5 is tilted to the front side or the back side by the connecting portion 13, so The portion is bent to the front side or the back side.

  In this way, the connecting portion 13 connects and supports the tail wing 5 so as to be tiltable with respect to the airframe 2 so as to be bent on both the front and back sides. The connection part 13 is comprised as a hinge part which supports the tail 5 so that rotation with respect to the body 2 is possible in a predetermined angle range so that rotation is possible.

  The tail 5 is in a straight state (not tilted) with respect to the airframe 2 when the flying object 1 is moving vertically up and down and hovering, and the flying object 1 is in the lateral direction (horizontal). In the state of moving in the direction), it tilts periodically corresponding to the rotation of the airframe 2.

  As shown in FIG. 2, the operation of the tail 5, that is, the tilting operation of the tail 5 with respect to the body 2 is controlled by the microcomputer 7. Specifically, the operation of the tail 5 is controlled by a servo motor 14 that receives a signal from the microcomputer 7.

  The servo motor 14 has a built-in control unit. Based on a signal (for example, a pulse signal) received from the microcomputer 7 by the control unit, the rotation shaft 14a serving as the output shaft of the servo motor 14 is arbitrarily set within a predetermined angle range. Rotate to an angle of. As shown in FIG. 1, the servo motor 14 is connected to the tail 5 via a link mechanism 15. Then, the rotation of the rotating shaft 14 a of the servo motor 14 is converted by the link mechanism 15 into a movement of tilting the tail 5 with respect to the body 2 by the connecting portion 13, and transmitted to the tail 5.

  One end of the link mechanism 15 is connected to the rotating shaft 14 a of the servo motor 14, and the other end of the link mechanism 15 is connected to a connecting portion 5 a provided at a predetermined position of the tail blade 5. The operation of the tail 5 is controlled so as to have an arbitrary tilt angle according to the rotation of the rotating shaft 14a of the servo motor 14. As the configuration of the link mechanism 15, an appropriate configuration can be adopted as long as the rotation of the rotating shaft 14 a of the servo motor 14 can be transmitted as a tilting operation with respect to the body 2 by the connecting portion 13 of the tail 5. .

  The geomagnetic sensor 6 is provided in the machine body 2 and functions as an azimuth detecting unit that detects the azimuth in which the machine body 2 is facing. In the present embodiment, the geomagnetic sensor 6 is held in a fixed state at a predetermined position on the front side surface of the machine body 2. The geomagnetic sensor 6 detects the azimuth (azimuth angle) that the machine body 2 that rotates by the reaction force of the propeller 3 is currently facing by detecting the geomagnetism.

  Specifically, in the present embodiment, the geomagnetic sensor 6 detects the orientation of the aircraft 2 in the state of flying while rotating by the lift of the propeller 3 with reference to the orientation of the front surface of the aircraft 2. To do. That is, the geomagnetic sensor 6 detects which direction the surface on the front side of the airframe 2 rotating in flight is facing.

  In other words, the geomagnetic sensor 6 is provided in the airframe 2 so that it can detect which direction the surface on the front side of the airframe 2 rotating in flight is facing. However, the orientation of the airframe 2 that serves as a reference when detecting the orientation by the geomagnetic sensor 6 is not limited to the orientation of the surface on the front side of the airframe 2 and is appropriately set depending on the shape of the airframe 2 and the like.

  As shown in FIG. 2, the detection signal from the geomagnetic sensor 6 is input to the microcomputer 7. Then, based on the sensor output from the geomagnetic sensor 6, the microcomputer 7 calculates the direction in which the machine body 2 is facing. In the following description, the azimuth of the airframe 2 detected by the geomagnetic sensor 6 is also simply referred to as “the azimuth of the airframe 2”.

  The microcomputer 7 functions as a controller that controls each part of the aircraft 1. The microcomputer 7 includes a CPU, a flash memory, a ROM, and the like, and controls each part of the flying object 1 by executing predetermined arithmetic processing according to a program written in advance. That is, the microcomputer 7 controls the autonomous navigation of the flying object 1 by controlling the operations of the propeller 3 and the tail 5 according to a predetermined program inputted in advance.

  The microcomputer 7 is provided in the machine body 2. In the present embodiment, the microcomputer 7 is held in a fixed state at a predetermined position on the front surface of the body 2.

  The flight operation of the air vehicle 1 having the above configuration will be described with reference to FIGS. First, among the flight operations of the flying object 1, the vertical movement of the flying object 1 and the hovering (hereinafter collectively referred to as "vertical flight operation") will be described. As described above, the flying vehicle 1 in flight is in a state in which the airframe 2 is rotated in the opposite direction to the propeller 3 by the reaction force of the rotation of the propeller 3 while obtaining lift by the rotation of the propeller 3.

  The vertical flight operation of the flying object 1 is performed by rotation control of the propeller 3 for obtaining lift. Therefore, in the state in which the flying object 1 is performing the vertical flight operation, the output of the motor 4 that drives the propeller 3 is controlled, so that the flying object 1 moves vertically, moves vertically, and hovers. Is performed, and the altitude of the flying object 1 is adjusted.

  As shown in FIG. 3A, in the flying object 1 during the vertical flight operation, the tail 5 is in a straight state (not tilted) with respect to the airframe 2. The flying object 1 during the vertical flight operation is in such a posture that the plate surfaces of the fuselage 2 and the tail 5 are substantially along the vertical direction due to the air resistance received by the rotation of the fuselage 2 and the weight of the fuselage 2 itself.

  Next, the lateral movement (horizontal direction) of the flying object 1 (hereinafter referred to as “horizontal flight operation”) will be described. In the horizontal flight operation of the flying object 1, the airflow around the airframe 2 that is rotated by the reaction torque of the propeller 3 is changed by the operation of the tail 5 while flying by receiving lift from the rotation of the propeller 3 to change the airframe 2 By tilting, a horizontal component of lift by the propeller 3 is generated and moved in the lateral direction.

  Therefore, in the flying object 1 during the horizontal flight operation, the tilting operation of the tail 5 with respect to the airframe 2 is performed. That is, as shown in FIG. 3A, the tail 5 is tilted with respect to the fuselage 2 from the straight state with respect to the fuselage 2 as shown in FIG. 3B (see arrow B1). ). In FIG. 3, the tail 5 is tilted toward the front side with respect to the body 2.

  As shown in FIG. 3B, when the tail 5 tilts, the airflow received by the airframe 2 changes, and as shown in FIG. 3C, the flying object 1 is tilted. Here, the flying object 1 tilts in a direction corresponding to the tilting direction of the tail 5 with respect to the fuselage 2 so that the rotation axis of the propeller 3 is tilted. That is, as shown in FIG. 3 (b), when the tail 5 tilts toward the front side with respect to the airframe 2, as shown in FIG. 3 (c), the flying object 1 is on the front side (left side in FIG. 3). Tilt to tilt forward.

  As shown in FIG. 3 (c), when the flying object 1 is tilted to the front side, a horizontal component of the lifting force by the propeller 3 is generated in the front direction (left direction in FIG. 3), and the flying object 1 moves forward. . That is, as shown in FIGS. 3A and 3B, in the flying object 1, the lift generated by the rotation of the propeller 3 is tilted from the state during the vertical flight operation represented by the vertically upward vector V 0. When the operation is performed, the flying object 1 tilts and proceeds to the tilted side as shown in FIG.

  As the flying object 1 tilts, the direction of the vector V0 also tilts as the rotation axis of the propeller 3 tilts as shown in FIG. 3C, and the vertically upward vector V1 and the horizontal vector V2 are Arise. Thereby, the flying object 1 obtains a thrust (see vector V2) that proceeds in the lateral direction (horizontal direction).

  As described above, the tail 5 changes the flow of the airflow that is resisted by the rotation of the airframe 2 by the reaction force caused by the rotation of the propeller 3, thereby causing the airfoil 2 to tilt in a predetermined tilt direction in which the rotation axis of the propeller 3 is inclined. It functions as a movable wing that can be tilted. Here, the predetermined tilting direction of the airframe 2 corresponds to the direction in which the flying object 1 performing the horizontal flight operation travels. Therefore, the predetermined tilt direction of the airframe 2 corresponds to the direction in which the tail 5 tilts with respect to the airframe 2 (front side / back side direction).

  In the flying object 1 during the horizontal flight operation, the tilting operation of the tail 5 as described above is periodically performed in accordance with the rotation of the airframe 2. In other words, the tilt of the tail 5 is performed as a vibration operation having the same cycle as the rotation of the airframe 2 due to the reaction force of the propeller 3, so that the airframe 2 is always tilted in a certain direction, and the horizontal direction of the aircraft 1 is obtained. Can be moved to. Here, the fixed direction in which the airframe 2 tilts is a predetermined tilting direction with respect to the airframe 2, and corresponds to the direction in which the flying body 1 performing the horizontal flight operation travels.

  Specifically, a case where the flying object 1 moves in a predetermined movement direction in the horizontal direction will be described. As shown in FIGS. 4 (a) and 5 (a), in the horizontal flight operation of the flying object 1, the timing when the direction of the airframe 2 rotated by the reaction force of the propeller 3 is directed to a predetermined moving direction, in other words, At the timing when the front side of the airframe 2 faces a predetermined movement direction, the tail 5 tilts to the predetermined movement direction side, that is, the front side.

  Then, as shown in FIGS. 4B and 5B, in the process in which the airframe 2 is rotated by the reaction force of the propeller 3, the airframe 2 is rotated 180 °, and the orientation of the airframe 2 is set to a predetermined movement direction. The tail 5 tilts to the predetermined movement direction side, that is, the back side at the timing when facing the opposite direction, in other words, the timing when the back side of the airframe 2 faces the predetermined movement direction side. Similarly, as shown in FIGS. 4 (c) and 5 (c), when the fuselage 2 is further rotated 180 ° and the orientation of the fuselage 2 is directed to a predetermined movement direction, the tail 5 is Tilt to the moving direction side.

  As described above, in the horizontal flight operation of the flying object 1, in synchronization with the rotation operation of the airframe 2 rotated by the reaction force of the propeller 3, every time the airframe 2 rotates 180 °, the tail 5 moves in a predetermined moving direction. The tilting operation is performed as a periodic vibration operation. That is, the tail 5 is tilted in the direction opposite to the front side and the back side with respect to the airframe 2 as an operation that vibrates sinusoidally in synchronization with the rotation of the airframe 2, and the tilt direction is always the direction of the predetermined movement direction By doing so, the state in which the flying object 1 is tilted in the predetermined moving direction is maintained, and the flying object 1 advances in the tilting direction.

  As described above, the flying object 1 periodically moves the tail 5 in synchronization with the rotation of the airframe 2, so that the airframe 2 responds to the traveling direction (predetermined movement direction) of the airframe 2 in the horizontal direction. The flow of airflow that inclines is generated intermittently. Thereby, the flying object 1 moves in a predetermined movement direction in the horizontal flight operation. And the horizontal flight operation | movement of the flying body 1 also stops because the periodic operation | movement of the tail 5 synchronized with rotation of the body 2 stops. In this way, the position of the flying object 1 in the horizontal direction is controlled.

  The periodic operation of the tail 5 synchronized with the rotation of the airframe 2 due to the reaction force of the propeller 3 is performed under the control of the microcomputer 7 based on the detection signal from the geomagnetic sensor 6. The microcomputer 7 uses the geomagnetic sensor 6 to detect which direction the surface on the front side of the body 2 is currently facing. In the microcomputer 7, the moving direction of the flying object 1 in the horizontal direction is designated as a predetermined pointing direction by a program or the like input in advance.

  Therefore, the microcomputer 7 has a servo motor so that the tail 5 is tilted toward the indicated direction at the timing when the direction of the body 2 is directed to the indicated direction and the timing at which the direction of the body 2 is directed to the opposite direction to the indicated direction. The operation of the tail 5 is controlled by sending a control signal to 14. That is, the microcomputer 7 synchronizes with the rotation of the airframe 2 due to the reaction force of the propeller 3 in accordance with the orientation of the airframe 2 detected by the geomagnetic sensor 6, and the tail 5 The operation of the tail 5 is controlled so as to tilt toward a predetermined pointing direction.

  For example, when the predetermined designated direction designated in the microcomputer 7 is “south”, the microcomputer 7 has a timing when the direction of the airframe 2 becomes “south” and a timing when the direction of the airframe 2 becomes “north”. At both timings, the tail 5 is tilted toward the “south”. As a result, the flying object 1 moves toward “south” while maintaining a state of tilting toward “south”.

  As described above, the microcomputer 7 determines that the machine body 2 rotated by the reaction force of the propeller 3 is based on the direction of the machine body 2 detected by the geomagnetic sensor 6 (the direction in which the machine body 2 is directed). The movement of the airframe 2 is controlled by operating the tail 5 periodically so that the airframe 2 tilts in accordance with the instructed direction in synchronism with the timing when the instructed direction is directed. In the horizontal flight operation of the flying object 1, the vertical component of the lift of the propeller 3 is reduced by tilting the airframe 2 (see FIG. 3C), so that the altitude of the flying object 1 is maintained. In this case, control for increasing the rotation speed of the motor 4 is appropriately performed.

  In addition, the flying object 1 of the present embodiment autonomously navigates between designated points or between designated points by performing navigation control using GPS (Global Positioning System). Therefore, as shown in FIGS. 1 and 2, the flying object 1 includes a GPS sensor 16 that receives a signal (GPS signal) from a GPS satellite 20. In the present embodiment, the GPS sensor 16 is held in a fixed state at a predetermined position on the front surface of the body 2.

  The GPS sensor 16 has a function as a GPS receiver and a function as a GPS antenna, and communicates with a plurality of GPS satellites 20. A GPS signal from the GPS satellite 20 received by the GPS sensor 16 is input to the microcomputer 7 and detected as the current position of the aircraft 1.

  Based on the GPS signal received by the GPS sensor 16, the microcomputer 7 detects the spatial coordinates and time including the longitude, latitude, and altitude of the position where the aircraft 2 of the aircraft 1 is currently present (current location of the aircraft 1). To do. For this reason, the microcomputer 7 has a function part which detects a space coordinate and time based on the GPS signal which the GPS sensor 16 received.

  The spatial coordinates and time of the current position of the flying object 1 acquired by the GPS sensor 16 are used for autonomous navigation control of the flying object 1 performed by the microcomputer 7 according to a predetermined program.

  For example, the microcomputer 7 updates the control amounts for the propeller 3 and the tail 5 based on the signals sent from the geomagnetic sensor 6 and the GPS sensor 16 as needed, with the target of the route of navigation performed according to a predetermined program. Perform feedback control. Thereby, the microcomputer 7 causes the horizontal position (latitude, longitude) of the flying object 1, the vertical position (altitude) of the flying object 1, the moving direction (traveling direction) of the flying object 1, and the movement of the flying object 1. Control speed, etc.

  As described above, the microcomputer 7 detects the current position of the airframe 2 based on the GPS signal received by the GPS sensor 16, and controls the movement of the airframe 2 using the detected current position of the airframe 2.

  As described above, the flying object 1 has a GPS communication function, and the navigation control is performed using the GPS communication function, thereby reducing the influence of weather conditions and the like in the autonomous navigation of the flying object 1. And can navigate accurately. For example, when the wind is strong as the weather condition, the flying object 1 is swept away by the wind and the deviation from a predetermined navigation route increases, but the current position of the airframe 2 detected by the GPS function is used for the navigation control of the flying object 1. By using it, it becomes possible to navigate while correcting the navigation route of the vehicle 1, and it is possible to perform accurate navigation.

  In addition to the autonomous navigation control by the microcomputer 7, the flying object 1 of the present embodiment has a configuration for performing wireless operation (remote operation). For this reason, as shown in FIGS. 1 and 2, the aircraft 1 includes an RC receiver 17 as a receiver that receives a radio signal for remotely operating at least one of the motor 4 and the tail 5. The RC receiver 17 is held in a fixed state at a predetermined position on the front side surface of the body 2.

  As shown in FIG. 2, the RC receiver 17 receives a radio signal from a radio pilot 30 operated by a pilot maneuvering the flying object 1. The radio signal received by the RC receiver 17 from the radio pilot 30 includes a control signal for controlling at least one of the operation of the motor 4 that drives the propeller 3 and the operation of the tail 5. A radio signal from the radio pilot 30 received by the RC receiver 17 is input to the microcomputer 7 and used for controlling the operation of the motor 4 or the tail 5.

  Specifically, when the microcomputer 7 controls the operation of the motor 4 based on the radio signal received by the RC receiver 17, the microcomputer 7 corresponds to the control amount instructed by the operation of the radio pilot 30. A control amount of the motor 4 is determined via the amplifier 12, and the rotational speed (rotational speed) of the motor 4 is controlled. When the microcomputer 7 controls the operation of the tail 5 based on the radio signal received by the RC receiver 17, the microcomputer 7 corresponds to the control amount instructed by the operation of the radio pilot 30. A control amount is determined, and the tilt angle of the tail 5 is controlled.

  In order to perform such control by radio control, the microcomputer 7 has a functional unit for controlling the operation of the motor 4 or the tail 5 based on the radio signal received by the RC receiver 17. As described above, the microcomputer 7 controls the operation of at least one of the motor 4 and the tail 5 based on the radio signal received by the RC receiver 17. The radio piloting by the radio pilot 30 using the RC receiver 17 is used, for example, as an aid for airframe control when the aircraft 1 is taking off and landing.

  As described above, since the flying object 1 has a configuration for performing wireless control, the flying object 1 can be remotely operated in a range that is visible to the operator of the flying object 1. Thereby, safety can be ensured in the navigation control of the flying object 1.

  As described above, according to the vehicle 1 capable of autonomous navigation, it is possible to navigate altitude and distance that cannot be controlled by wireless maneuvering and to automatically acquire weather observation data. Thus, it is possible to perform navigation control arbitrarily by the pilot within a range that can be visually recognized by the pilot. From the viewpoint of ensuring safety, a configuration in which control by radio control by the radio pilot 30 using the RC receiver 17 is preferentially performed with respect to autonomous navigation control and can be instantaneously switched to manual flight. It is preferable to adopt. In the present embodiment, the RC receiver 17 may be configured by hardware common to a controller realized by the microcomputer 7.

  In the flying object 1 of the present embodiment, control for maintaining the altitude of the airframe 2 (hereinafter referred to as “altitude maintenance control”) is performed during the vertical flight operation or the horizontal flight operation. For this reason, the flying object 1 includes altitude detection means for detecting the altitude of the airframe 2. The altitude maintenance control is performed by the microcomputer 7 based on the altitude of the airframe 2 detected by the altitude detecting means.

  The aircraft 1 of the present embodiment uses the altitude of the current position of the airframe 2 detected by the GPS sensor 16 as described above in altitude maintenance control. That is, in this embodiment, the GPS sensor 16 functions as an altitude detecting unit that detects the altitude of the airframe 2.

  In altitude maintenance control, the microcomputer 7 targets the altitude of the airframe 2 by performing feedback control by comparing the target value for the altitude of the airframe 2 input in advance with the detection value detected by the GPS sensor 16. The operation of the motor 4 is controlled so as to hold the value.

  Therefore, at the time of altitude maintenance control, a target value for the altitude of the airframe 2 is input to the microcomputer 7 in advance. The target value for the altitude of the airframe 2 used for altitude maintenance control is input as part of a program for autonomous navigation of the aircraft 1, for example.

  The microcomputer 7 compares the altitude target value of the airframe 2 input in advance with the current altitude detection value of the airframe 2 detected by the GPS sensor 16, and based on the comparison result, The control amount of the motor 4 is adjusted via the motor amplifier 12 so that the value matches the detected value. The microcomputer 7 has a functional unit for performing altitude maintenance control based on the GPS signal received by the GPS sensor 16 as described above.

  As described above, the altitude maintenance control is performed on the air vehicle 1, so that the influence of the weather condition and the like can be reduced in the autonomous navigation of the air vehicle 1, and the altitude of the airframe 2 is more accurate. Navigation is possible.

  In the present embodiment, the GPS sensor 16 is used as the altitude detecting means for detecting the altitude of the airframe 2, but the altitude detecting means for performing altitude maintenance control is provided separately from the GPS sensor 16. An altimeter may be used. In this case, the microcomputer 7 performs feedback control on the altitude of the airframe 2 as described above based on the altitude information of the airframe 2 obtained by the altimeter.

  In addition, when the aircraft 1 of the present embodiment has landed after completing a predetermined navigation, in order to buffer the momentum that the airframe 2 falls to the ground surface, control is performed to perform hovering when reaching a predetermined height position from the ground ( Hereinafter referred to as “landing control”). In order to perform landing control, the flying object 1 has an ultrasonic sensor 18 that functions as a height position detection unit that detects the distance of the airframe 2 to the ground surface, as shown in FIGS. 1 and 2. The ultrasonic sensor 18 is held in a state of being fixed at a predetermined position on the front surface of the body 2.

  The ultrasonic sensor 18 oscillates ultrasonic waves from the sensor head, receives ultrasonic waves reflected from the ground surface by the sensor head, and measures the time from transmission to reception of the ultrasonic waves, that is, the distance to the ground surface, that is, the aircraft 2 height position is detected. For this reason, the ultrasonic sensor 18 is provided in the airframe 2 so that the sensor head faces downward.

  The microcomputer 7 performs landing control based on the distance to the ground surface detected by the ultrasonic sensor 18 in the process of descending movement performed when the flying object 1 is landing. Specifically, in the landing control, the microcomputer 7 drives the motor 4 that drives the propeller 3 so that the flying object 1 enters a hovering state when the distance of the airframe 2 to the ground surface reaches a predetermined distance. To control the operation.

  Then, the microcomputer 7 controls the operation of the motor 4 so that the flying object 1 is gradually lowered after the flying object 1 is temporarily hovered when the flying object 1 is landed. The predetermined distance with respect to the ground surface of the airframe 2 set in such landing control is set to a distance of about 5 to 10 m, for example.

  A functional unit for performing such landing control is provided in the microcomputer 7. At the time of landing control, the microcomputer 7 previously inputs the distance from the ground surface of the airframe 2 (the height position of the airframe 2) where the airframe 1 is once hovered as described above as a series of programs, data tables, and the like. Is done.

  Thus, the microcomputer 7 controls the operation of the motor 4 so that the airframe 2 will hover when the distance to the ground surface detected by the ultrasonic sensor 18 reaches a predetermined distance inputted in advance.

  By performing the landing control as described above on the flying object 1, the flying object 1 can be landed gently with respect to the ground surface, and failure or damage due to the landing of the flying object 1 can be prevented. Thereby, the lifetime of the flying object 1 can be improved and the cost can be reduced more effectively. As the height position detection means used for landing control by the flying object 1, well-known sensors such as a photoelectric sensor and a proximity sensor can be used in addition to the ultrasonic sensor as in this embodiment.

  Hereinafter, as an application example of the flying object 1 of the present embodiment, an example of a series of navigation controls when the flying object 1 is used as a weather observation apparatus will be described with reference to FIG. When the flying object 1 is used as a weather observation device, in the flying object 1, a measuring instrument for measuring a predetermined meteorological element to be observed, such as a temperature sensor, is mounted on the airframe 2. In this example, a case where a temperature sensor is mounted as a measuring instrument for weather observation will be described.

  As shown in FIG. 6, in the navigation control of the aircraft 1 according to the present example, first, the aircraft 1 is powered on, whereby the microcomputer 7 is initialized and the GPS sensor 16 is initialized. As a result, reception of a GPS signal from the GPS satellite 20 is started.

  Next, driving of the propeller 3 by the motor 4 is started, and the flying object 1 is vertically moved at a predetermined ascent rate (ascent speed) set in advance ((A) → (B)). In the process of ascending the flying object 1, the temperature at each altitude point is measured and recorded by the temperature sensor while the spatial coordinates of the flying object 1 are detected based on the GPS signal received by the GPS sensor 16. .

  Next, the flying object 1 performs a horizontal flight operation toward a predetermined pointing direction ((B) → (C) → (D)). That is, the periodic oscillating motion of the tail 5 synchronized with the rotation of the airframe 2 due to the reaction force of the rotation of the propeller 3 is performed, and the flying object 1 moves horizontally toward a predetermined pointing direction. Even in the process of horizontal movement of the flying object 1, the temperature at each altitude point is measured by the temperature sensor while the spatial coordinates of the flying object 1 are detected based on the GPS signal received by the GPS sensor 16. To be recorded. Further, in the process of horizontal movement of the flying object 1, navigation control and altitude maintenance control using the GPS function as described above are appropriately performed.

  When the flying object 1 reaches a predetermined return point set in advance by horizontal movement ((B) → (C) → (D)), the flying object 1 returns to the observation start point ((D). → (C) → (B)), and moves vertically downward ((B) → (A)) at a predetermined lowering rate (lowering speed) set in advance. In the descending process of the air vehicle 1, the landing control as described above is performed, and when the distance of the airframe 2 with respect to the ground surface 40 reaches a preset distance, the air vehicle 1 is once in a hovering state. Then, it will land gently on the surface 40.

  Such a series of navigation control for the aircraft 1 is performed as autonomous navigation based on a program or the like input in advance in the microcomputer 7 using GPS signals. However, the RC receiver 17 is used in a range where the operator of the flying object 1 can visually recognize, and the radio control by the radio control unit 30 is appropriately performed.

  In the navigation control of the flying object 1, the observation start point for meteorological observation and the collection point for collecting the flying object 1 after the observation can be set to different points. In this case, for example, as shown in FIG. 6, when the flying object 1 reaches a predetermined return point set in advance by horizontal movement ((B) → (C) → (D)), the flying object 1 At that point, it starts to descend and land on the surface 40 ((D) → (E)).

  The aircraft 1 that landed on the ground surface 40 is in a stopped state. Then, the microcomputer 7 of the flying object 1 is connected to a computer or the like, and the observation data stored in the memory of the microcomputer 7 is read. As described above, observation data is collected, and weather observation by the flying object 1 is performed.

  The aircraft 1 according to the present embodiment can be used for various applications in addition to the above-described weather observation applications. For example, the flying object 1 of the present embodiment can be used as an imaging device that performs imaging from above by mounting a camera on the airframe 2. The flying object 1 of the present embodiment can also be applied as a hobby toy. In addition, the aircraft 1 of the present embodiment can be used as a wireless communication repeater by mounting a wireless communication device on the airframe 2.

  The aircraft 1 of the present embodiment described above is an embodiment of the present invention, and various modifications can be considered. For example, the flying object 1 of the present embodiment employs the motor 4 as a drive source for driving the propeller 3, but the drive source for driving the propeller 3 may be an engine (internal combustion engine). In this case, the battery 10 can be omitted.

  Moreover, although the flying body 1 of this embodiment is provided with the tail wing 5 as a movable wing which is the structure for moving to a horizontal direction, a movable wing is not limited to this. For example, the movable wing for moving the airframe 2 in the lateral direction may be provided on a corner side (base angle side) other than the apex angle side in the isosceles triangular airframe 2. That is, as a movable wing for moving the airframe 2 in the lateral direction, depending on the configuration of the airframe 2, by changing the flow of the airflow that receives resistance as the airframe 2 rotates by the reaction force of the propeller 3, Any structure that can tilt the machine body 2 in a predetermined tilting direction in which the rotation axis of the propeller 3 tilts may be used.

  The flying object 1 of the present embodiment employs the geomagnetic sensor 6 as means for detecting the orientation of the airframe 2, but as means for detecting the orientation of the airframe 2, various types of sensors such as a gyro sensor and an acceleration sensor are used. These sensors can be used. Moreover, the function as a means to detect the azimuth | direction of the body 2 can also be acquired by arrange | positioning and providing a several GPS sensor in a mutually different position.

  In addition, the arrangement of various devices such as the geomagnetic sensor 6 and the microcomputer 7 provided in the airframe 2 in the aircraft 1 is not particularly limited, and is appropriately set in relation to other devices in the airframe 2. For example, various devices provided in the airframe 2 are arranged so that the weight of the airframe 2 due to the reaction force of the propeller 3 is considered, and the left and right weights are centered on the support pillar 11.

  According to the aircraft 1 of the present embodiment as described above, the position of the airframe 2 can be controlled without canceling the torque as a reaction of the rotation of the propeller 3 for obtaining lift, and the structure and the small size are simple. A lightweight configuration can be easily realized, maintenance is easy with few failures, and it can be manufactured at low cost.

  The flying body 1 of the present embodiment employs a unique airframe structure that flies while rotating the airframe 2 by the reaction force torque of the propeller 3 by electronic technology. In particular, the aircraft 1 of the present embodiment is essentially different from existing aircraft such as a rotary wing aircraft due to the relationship between the center of gravity of the aircraft and the center of pressure. The aircraft such as the existing rotary wing aircraft has canceled the reaction force of the propeller to ensure the maneuverability. However, according to the aircraft 1 of the present embodiment, the propeller reaction force is obtained by the GPS function and various sensors. It is possible to greatly simplify the structure of the airframe by electronically controlling the airframe while it is still spinning.

  The flying object 1 of the present embodiment is limited only by the physical size and loading weight of measuring instruments, various sensors, etc., and can fly with autonomous stability. Furthermore, according to the aircraft 1 of the present embodiment, the following advantages are obtained. The space required for take-off and landing can be as small as a tatami mat, so it can be observed from the roof of a building. Further, since the ascending / descending is performed by a simple mechanism, the device is inexpensive and robust. In addition, since it is lighter and smaller than the prior art, it is possible to reduce the influence on others when dropped. Further, since the mechanical structure and the control structure are simple, the cost is low, the reliability is high, and the maintenance is easy.

1 Aircraft 2 Aircraft 3 Propeller (Rotor)
4 Motor (drive source)
5 Tail (movable wing)
6 Geomagnetic sensor (azimuth detection means)
7 Microcomputer (controller)
16 GPS sensor 17 RC receiver 18 Ultrasonic sensor (height position detecting means)
20 GPS satellite 30 Radio pilot

Claims (5)

A rotor that generates lift by rotating;
A drive source for rotating the rotor;
A body that holds the rotor and the drive source, receives a reaction force caused by rotation of the rotor, rotates in a direction opposite to the rotation direction of the rotor, and flies by lift obtained by rotation of the rotor; ,
By changing the flow of the airflow that is provided so as to be movable with respect to the airframe and receives resistance as the airframe rotates by the reaction force, the airframe is moved in a predetermined tilting direction in which the rotation axis of the rotor is inclined. Tilting movable wings,
Azimuth detecting means provided on the airframe for detecting the azimuth facing the airframe;
Provided in the body, based on the direction detected by said azimuth detection means, said timing the machine body which is rotated by a reaction force faces the predetermined instruction orientation is indicated as the direction of travel of the aircraft, and the aircraft said Controlling the operation of the movable wing in synchronism with the rotation of the airframe so that the movable wing tilts toward the indicated azimuth with respect to the airframe at a timing opposite to the indicated azimuth. A controller that controls the movement of the airframe by periodically operating the movable wing so that the tilt direction is tilted corresponding to the indicated direction.
Flying body. A GPS sensor for receiving signals from GPS satellites,
The controller detects the current position of the aircraft based on the signal received by the GPS sensor, and controls the movement of the aircraft using the detected current position.
The flying object according to claim 1. A receiver for receiving a radio signal for remotely operating at least one of the drive source and the movable blade;
The controller controls the operation of at least one of the drive source and the movable blade based on the radio signal received by the receiver.
The flying object according to claim 1 or 2. Comprising altitude detection means for detecting the altitude of the aircraft,
The controller holds the altitude of the airframe at the target value by performing feedback control by comparing a target value for the altitude of the airframe input in advance and a detection value detected by the altitude detecting means. Controlling the operation of the drive source,
The flying object according to any one of claims 1 to 3. A height position detecting means for detecting a distance of the aircraft relative to the ground surface;
The controller controls the operation of the driving source so that the airframe hovers when the distance detected by the height position detection means reaches a predetermined distance input in advance.
The flying object according to any one of claims 1 to 4.

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