JP2022032652A - Device for releasing drone from restrained state, drone, and method for releasing drone from restrained state - Google Patents

Abstract

To provide a device for releasing a drone from a restrained state, which can release the drone, restrained by an obstacle, from the restrained state.SOLUTION: A device 2 for releasing a drone from a restrained state comprises: a buffer member 11 that is arranged on an outer peripheral part of the drone 1 and that can be deformed depending on encapsulation and discharge of a gas; an air pump (gas discharge mechanism) 17 that discharges the gas from an inside of the buffer member 11; and a drive control part 18 that deforms the buffer member 11 by driving the air pump 17.SELECTED DRAWING: Figure 2

Description

The present invention relates to a drone restrained state release device, and more particularly to a device for releasing a drone restrained by an obstacle from the restrained state.
The present invention also relates to a drone provided with such a drone restraint state release device.
Further, the present invention also relates to a drone restraint state withdrawal method for releasing a drone restrained by an obstacle from the restraint state.

In recent years, the use of unmanned aerial vehicles called drones has become widespread in a wide range of fields such as various surveys, inspections, observations, and photography.
A drone generally has a propulsion machine with a plurality of rotary wings and a control unit for driving and controlling the propulsion device. However, in order to prevent damage due to contact with an obstacle, a guard surrounding the rotary wings, the control unit, etc. Drones with frames are being developed.

For example, Patent Document 1 discloses a drone in which a plurality of rotary blades and a control unit as a whole are surrounded by a polyhedral guard frame composed of a combination of a plurality of beam members.
Further, Patent Document 2 discloses a drone in which an outer peripheral portion of a plurality of rotary blades is surrounded by a ring-shaped guard frame.

Japanese Unexamined Patent Publication No. 2018-58562 Japanese Unexamined Patent Publication No. 2016-182940

By providing such a guard frame, even if the drone in flight comes into contact with an obstacle, the rotor blade or the control unit or the like is protected, and the drone can be prevented from being damaged or crashed.

However, for example, when a drone equipped with a camera is to be flown inside the building for the purpose of photographing an inspection point inside a factory building that is old and has many obstacles, a guard frame provided in the drone is provided. May get stuck between obstacles and the drone may be restrained by the obstacles. In this way, if the drone falls into a restrained state, the drone cannot move even if a propulsion machine composed of rotary wings or the like is driven.
For a drone that has been restrained, rescue work by a worker is required, and there is a problem that it takes a lot of time and effort to rescue the drone.

The present invention has been made to solve such a conventional problem, and an object of the present invention is to provide a drone restraint state release device capable of releasing a drone restrained by an obstacle from the restraint state. ..
It is also an object of the present invention to provide a drone provided with such a drone restraint state release device.
Further, it is also an object of the present invention to provide a drone restraint state withdrawal method capable of releasing a drone restrained by an obstacle from the restraint state.

The drone restrained state release device according to the present invention is a device for releasing a drone restrained by an obstacle from the restrained state, and is a shock absorber arranged on the outer peripheral portion of the drone and deformable according to the encapsulation and discharge of gas. It is provided with a gas discharge mechanism for discharging gas from the inside of the cushioning member and a drive control unit for deforming the cushioning member by driving the gas discharge mechanism.

A wireless switch that receives a wireless signal and is turned on or off is provided, and the drive control unit can be configured to drive the gas discharge mechanism when the wireless switch is on.
Alternatively, it is provided with a restraint detection unit that detects that the drone is in a restrained state, and the drive control unit is configured to drive the gas discharge mechanism when the restraint detection unit detects that the drone is in a restrained state. You can also do it.

The restraint detection unit puts the drone in a restrained state when the pressure sensor that detects the internal pressure of the cushioning member and the internal pressure of the cushioning member detected by the pressure sensor exceed a preset threshold value for a predetermined time. It is preferable to include a restraint determination unit for determining the existence.
Alternatively, the restraint detection unit has a tension sensor that detects the tension acting on the cushioning member, and the drone is in a restrained state when the tension detected by the tension sensor exceeds a preset threshold value over a predetermined time. It is preferable to include a constraint determination unit for determining.

The cushioning member is preferably made of an electrically insulating material.
The gas discharge mechanism can consist of an air pump or a suction fan.
Further, the drone includes a drone body for performing unmanned flight and a guard frame surrounding the whole or a part of the drone body, and the cushioning member can be configured to be attached to the guard frame.

The drone according to the present invention includes the above-mentioned drone restraint state release device.

The drone restrained state release method according to the present invention is a method in which a cushioning member that can be deformed according to the filling and discharging of gas is provided on the outer peripheral portion, and the drone restrained by an obstacle is released from the restrained state. It is a method including a step of releasing the drone from the restrained state by discharging gas from the inside of the surface and deforming the cushioning member.

According to the present invention, the drive control unit drives the gas discharge mechanism to discharge gas from the inside of the cushioning member arranged on the outer peripheral portion of the drone to deform the cushioning member, and thus is restrained by an obstacle. It is possible to remove the drone from the restrained state.

It is a perspective view which shows the drone provided with the drone restraint state release device which concerns on Embodiment 1 of this invention. It is a block diagram which shows the structure of the drone provided with the drone restraint state release device which concerns on Embodiment 1. FIG. It is a perspective view which shows the drone flying in the vicinity of an obstacle. It is a perspective view which shows the drone which was restrained by an obstacle. It is a perspective view which shows the drone which got out of the restraint state. It is a block diagram which shows the structure of the drone provided with the drone restraint state release device which concerns on Embodiment 2. FIG. It is a perspective view which shows the drone provided with the drone restraint state release device which concerns on Embodiment 3. FIG. It is a partial plan view which shows the cushioning member in the drone restraint state release device which concerns on Embodiment 4. FIG. It is a perspective view which shows the drone provided with the drone restraint state release device which concerns on Embodiment 5. It is a perspective view which shows the drone provided with the drone restraint state release device which concerns on Embodiment 6.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.
Embodiment 1
FIG. 1 shows a drone 1 provided with a drone restraint state release device 2 according to the first embodiment.
The drone 1 has a drone main body 3 for performing unmanned flight and a polyhedral guard frame 4 that surrounds the entire drone main body 3.
The drone main body 3 has a housing 5, a plurality of motors 6 fixed to the housing 5, and a plurality of rotary blades (propellers) 7 connected to the plurality of motors 6. Further, the drone main body 3 has a camera 8 for photographing attached to the outside of the housing 5.

The guard frame 4 has rigidity and is rotatably held in a three-dimensional direction with respect to the drone body 3 by a gimbal mechanism (not shown), and is formed by combining a plurality of linear beam members 9. There is. The beam member 9 is preferably lightweight and has excellent strength, and can be formed from, for example, a carbon rod. Further, it is preferable that the surface of the guard frame 4 is made of an electric insulator so as not to cause an electric shock even when the drone 1 in flight comes into contact with an obstacle such as an electric wire. Therefore, when the beam member 9 is formed of carbon rods, it is preferable to use carbon rods having an insulating coating on the surface.

A cushioning member 11 is arranged on the outer peripheral portion of the guard frame 4 of the drone 1.
The cushioning member 11 is made of a flexible tubular body, has an annular shape surrounding the outer peripheral portion of the guard frame 4, and has a closed internal space. The cushioning member 11 forms a tubular body by rolling a film or sheet made of an electrically insulating material such as fluororesin (PTFE) or polycarbonate and heat-welding both end edges to each other, and further guards the tubular body. It can be formed by winding it around the outer peripheral portion of the frame 4 to form an annular shape, and heat-welding both ends of the tubular body to each other to seal the inside of the tubular body.
The cushioning member 11 can be attached to the guard frame 4 by fixing the inner peripheral portion of the annular cushioning member 11 to the beam member 9 constituting the guard frame 4 by adhesion or the like.

Since the tubular body forming the cushioning member 11 has flexibility, when air is sealed in the internal space of the cushioning member 11, the cushioning member 11 swells, and conversely, air is introduced from the internal space of the cushioning member 11. When the air is discharged, the cushioning member 11 shrinks, and the cushioning member 11 is configured to be deformable according to the filling and discharging of air.

For example, as shown in FIG. 1, the annular shape cushioning member 11 in which air is sealed in the internal space has an outer diameter D2 larger than the diameter D1 of the guard frame 4 having a polyhedral shape. Since the cushioning member 11 is wound around the outer peripheral portion of the guard frame 4, the cushioning member 11 has an outer diameter larger than the diameter D1 of the guard frame 4, regardless of the amount of air in the internal space of the cushioning member 11. However, as the air in the internal space of the cushioning member 11 is discharged from the state of FIG. 1, the cushioning member 11 gradually shrinks, and the outer diameter of the cushioning member 11 becomes smaller than that of D2.

Further, as shown in FIG. 1, a cushioning member deforming portion 12 for deforming the cushioning member 11 is attached to the inside of the guard frame 4 to which the inner peripheral portion of the annular cushioning member 11 is in contact. The cushioning member 11 and the cushioning member deforming portion 12 constitute the drone restraint state release device 2 according to the first embodiment.

FIG. 2 is a block diagram showing a configuration of a drone 1 provided with a drone restraint state release device 2.
The drone main body 3 includes a flight control unit 13 connected to a plurality of motors 6, a shooting control unit 14 connected to the camera 8, a wireless communication unit 15 connected to the flight control unit 13 and the shooting control unit 14. It has a battery 16.

The flight control unit 13 controls the rotation of each of the plurality of motors 6 based on the flight control signal input via the wireless communication unit 15. By controlling the rotational speeds of the plurality of rotors 7 connected to the plurality of motors 6, the drone 1 can fly at the speed, direction and altitude corresponding to the flight control signal.
The shooting control unit 14 controls shooting by the camera 8 based on a shooting control signal input via the wireless communication unit 15.
The wireless communication unit 15 receives the flight control signal and the imaging control signal wirelessly transmitted by the operator, transmits the flight control signal to the flight control unit 13, and transmits the imaging control signal to the imaging control unit 14.
The battery 16 supplies power to each part in the drone body 3.

Further, the cushioning member deforming portion 12 includes an air pump 17 connected to the internal space of the cushioning member 11, a drive control unit 18 connected to the air pump 17, a wireless switch 19 connected to the drive control unit 18, and a battery 20. have.
The air pump 17 constitutes a gas discharge mechanism, and air can be discharged from the inside of the cushioning member 11.
The drive control unit 18 drives the air pump 17 when the wireless switch 19 is in the ON state, and causes the air pump 17 to discharge air from the inside of the cushioning member 11.
The wireless switch 19 is turned on or off based on the wireless signal transmitted by the operator.
The battery 20 supplies power to each part in the cushioning member deforming part 12.

An operation panel 21 and a wireless signal transmitter 22 are arranged in the vicinity of the operator who operates the drone 1.
The operation panel 21 has a wireless communication unit 23 that is wirelessly connected to the wireless communication unit 15 of the drone main body 3, and an operation unit 24 that is connected to the wireless communication unit 23. The operation unit 24 includes various switches, and the operator can wirelessly transmit a flight control signal and a shooting control signal to the drone 1 via the wireless communication unit 23 by operating the operation unit 24. ..
The wireless signal transmitter 22 is wirelessly connected to the wireless switch 19 of the shock absorber deforming portion 12, and the operator transmits a wireless signal from the wireless signal transmitter 22 to the drone 1 to wirelessly connect the shock absorber deforming portion 12. The switch 19 can be turned on or off.

Next, the operation of the drone 1 provided with the drone restraint state release device 2 will be described.
A predetermined amount of air is previously sealed inside the cushioning member 11 of the drone restraint state release device 2, and as shown in FIG. 1, the cushioning member 11 has an outer diameter D2.
First, when the operator operates the operation unit 24 of the operation panel 21 to transmit the flight control signal to the drone 1 via the wireless communication unit 23, the flight control signal is transmitted to the drone main body 3 of the drone 1. It is received by the wireless communication unit 15 and transmitted from the wireless communication unit 15 to the flight control unit 13. The flight control unit 13 to which the flight control signal is input controls the rotation of the plurality of motors 6 based on the flight control signal, whereby the rotation speeds of the plurality of rotary blades 7 connected to the plurality of motors 6 are increased. Controlled and the flight of Drone 1 takes place.

In this way, when the drone 1 enters the factory building for the purpose of inspecting an aging factory building and reaches the vicinity of the inspection point, the operator operates the operation unit 24 of the operation panel 21. As a result, the shooting control signal is transmitted to the drone 1 via the wireless communication unit 23. The shooting control signal is received by the wireless communication unit 15 of the drone main body 3 of the drone 1, then transmitted from the wireless communication unit 15 to the shooting control unit 14, and the camera 8 is transmitted by the shooting control unit 14 to which the shooting control signal is input. It is controlled and the inspection points are photographed. The shooting data is transmitted from the wireless communication unit 15 to the wireless communication unit 23 of the operation panel 21 via the shooting control unit 14, and the shooting image is displayed on a monitor (not shown) of the operation panel 21. Alternatively, the shooting data shot by the camera 8 may be configured to be stored in a memory (not shown) mounted on the drone main body 3.

Here, in the inside of the dilapidated factory building where the drone 1 flies, for example, as shown in FIG. 3, a ladder-shaped obstacle B exists, and two columnar members P parallel to each other of the obstacle B It is assumed that the interval W1 has a value larger than the diameter D1 of the guard frame 4 of the drone 1 and smaller than the outer diameter D2 of the cushioning member 11.

When the guard frame 4 comes into contact with the obstacle B as the drone 1 flies, the guard frame 4 rotates with respect to the drone body 3 by a gimbal mechanism (not shown), whereby the drone 1 becomes an obstacle B. You can continue to fly without being restrained. However, when the drone 1 flies toward between the two columnar members P of the obstacle B, the distance W1 between the two columnar members P is larger than the diameter D1 of the guard frame 4 and the cushioning member. Since it is smaller than the outer diameter D2 of 11, as shown in FIG. 4, the flexible annular cushioning member 11 is sandwiched between the two columnar members P, and the drone 1 becomes an obstacle B. There is a risk of being restrained.

In this way, when the drone 1 falls into a restrained state due to the obstacle B, the drone 1 moves even if the operator transmits a flight control signal from the operation panel 21 to rotate the plurality of rotary wings 7. The position of the drone 1 is stagnant, and the image captured by the camera 8 is fixed without change.

Therefore, when the operator senses that the drone 1 is in the restrained state based on the stagnant position of the drone 1 or the fixed captured image, the operator transmits a radio signal from the radio signal transmitter 22 to the drone 1. , The wireless switch 19 of the cushioning member deforming portion 12 is turned on. As a result, the drive control unit 18 drives the air pump 17, and the air pump 17 discharges air from the inside of the cushioning member 11. As the air is discharged from the inside of the cushioning member 11, the cushioning member 11 gradually shrinks, and the outer diameter of the cushioning member 11 becomes smaller. Then, as shown in FIG. 5, when the cushioning member 11 has an outer diameter D3 smaller than the distance W1 between the two columnar members P of the obstacle B, the outer peripheral surface of the cushioning member 11 becomes the obstacle B. The drone 1 is separated from the two columnar members P of the above, and the drone 1 is separated from the restrained state by the obstacle B. That is, the drone 1 can fly again according to the flight control signal transmitted from the operation panel 21.

In this way, even when the drone 1 is restrained by the obstacle B, it is possible to easily remove the drone 1 from the restrained state without requiring a rescue operation by an operator.
Since the cushioning member 11 is in a state of being deflated by the air being discharged by the air pump 17, until the cushioning member 11 has the initial outer diameter D2 in case the drone 1 is restrained by some obstacle again. , It is necessary to enclose air inside the cushioning member 11.

In the drone restraint state release device 2 according to the first embodiment, since the air pump 17 is used as a gas discharge mechanism for discharging air from the inside of the cushioning member 11, the air pump 17 is driven via the drive control unit 18. Thereby, it can be configured to send air into the inside of the cushioning member 11 and enclose it.
As the gas discharge mechanism, a suction fan may be used in addition to the air pump 17. Further, the inside of the cushioning member 11 is set to a pressure higher than the atmospheric pressure outside the cushioning member 11, that is, a so-called positive pressure state, and a valve can be used as a gas discharge mechanism. By opening the valve, air can be discharged until the inside of the cushioning member 11 reaches atmospheric pressure. However, the cushioning member 11 needs to be deformed according to the discharge of air.

Further, in the first embodiment, the air pump 17 is turned on by transmitting a wireless signal from the wireless signal transmitter 22 arranged separately from the operation panel 21 to turn on the wireless switch 19 of the cushioning member deforming portion 12. Driven, but not limited to this. For example, the drone main body 3 and the cushioning member deforming portion 12 are electrically connected, and the operator operates the operation unit 24 of the operation panel 21 to transmit a wireless signal to the drone 1 via the wireless communication unit 23. However, it is also possible to transmit a wireless signal from the wireless communication unit 15 of the drone main body 3 that has received the wireless signal to the cushioning member deforming unit 12 to turn on the wireless switch 19.
By doing so, it is possible to transmit a wireless signal from the operation panel 21 to the drone 1 and discharge air from the inside of the cushioning member 11 without using the wireless signal transmitter 22.

In the first embodiment described above, as shown in FIG. 2, the cushioning member deforming portion 12 has a built-in dedicated battery 20 in addition to the battery 16 of the drone main body 3, but the present invention is not limited to this. .. If the drone main body 3 and the cushioning member deforming portion 12 are electrically connected and the battery 16 built in the drone main body 3 is configured to supply power to each part in the cushioning member deforming portion 12, the cushioning member is deformed. The battery 20 of the unit 12 can be omitted.

Embodiment 2
In the first embodiment described above, the operator who senses the restrained state of the drone 1 based on the stagnant position of the drone 1 or the fixed captured image transmits a radio signal from the radio signal transmitter 22 to obtain an air pump. Although the air was discharged from the inside of the cushioning member 11 by driving the 17th, the air from the inside of the cushioning member 11 is automatically discharged when the drone 1 is in the restrained state without requiring the operation by the operator. It can also be configured to discharge.

FIG. 6 is a block diagram showing a configuration of a drone 1A provided with the drone restraint state release device 2A according to the second embodiment.
The drone 1A has the drone restraint state release device 2A instead of the drone restraint state release device 2 in the drone 1 in the first embodiment, and has a drone body 3 and a polyhedral guard that surrounds the entire drone body 3. The frame 4 is the same as that used in the first embodiment.

The drone restraint state release device 2A has a cushioning member 11 arranged on the outer peripheral portion of the guard frame 4 and a cushioning member deforming portion 12A attached to the inside of the guard frame 4.
The cushioning member 11 is the same as that used in the first embodiment.

The cushioning member deformation unit 12A has the restraint determination unit 25 and the pressure sensor 26 in place of the wireless switch 19 in the cushioning member deformation unit 12 used in the first embodiment. That is, the cushioning member deforming unit 12A includes an air pump 17 connected to the cushioning member 11, a drive control unit 18 connected to the air pump 17, a restraint determination unit 25 connected to the drive control unit 18, and a restraint determination unit 25. It is equipped with a pressure sensor 26 connected to the battery 20 and a battery 20.
The pressure sensor 26 is connected to the internal space of the cushioning member 11 and detects the internal pressure of the cushioning member 11.
The restraint determination unit 25 determines that the drone 1 is in the restraint state when the internal pressure of the cushioning member 11 detected by the pressure sensor 26 exceeds a preset threshold value for a predetermined time. The air pump 17 is driven by the drive control unit 18.

As shown in FIG. 4, when the flexible annular cushioning member 11 is sandwiched between the two columnar members P of the obstacle B and the drone 1A is in a restrained state, the cushioning member Since 11 is relatively pushed by the two columnar members P, the internal pressure of the cushioning member 11 increases as compared with the case where the drone 1A is not in the restrained state as shown in FIG. Therefore, when the internal pressure of the cushioning member 11 detected by the pressure sensor 26 exceeds a preset threshold value over a predetermined time, the restraint determination unit 25 determines that the drone 1A is in the restraint state. Can be done.

The detection of the internal pressure of the cushioning member 11 by the pressure sensor 26 is always performed during the flight of the drone 1A. Then, when the internal pressure of the cushioning member 11 detected by the pressure sensor 26 exceeds a preset threshold value for a predetermined time, the restraint determination unit 25 determines that the drone 1A is in the restraint state. The air pump 17 is driven by the drive control unit 18, and air is automatically discharged from the inside of the cushioning member 11.

The internal pressure of the cushioning member 11 gradually decreases as the air is discharged from the inside of the cushioning member 11, but the internal pressure of the cushioning member 11 becomes the internal pressure when the drone 1A is not in the restrained state as shown in FIG. Air is discharged by the air pump 17 until they become equal. When the internal pressure of the cushioning member 11 drops to equal the internal pressure when the drone 1A is not in the restrained state, it is determined that the pushing of the cushioning member 11 by the obstacle B has been eliminated, and at this time, it is shown in FIG. As a result, the outer diameter D3 of the cushioning member 11 becomes smaller than the distance W1 between the two columnar members P of the obstacle B due to the discharge of air, and the drone 1A is released from the restrained state by the obstacle B.

In this way, when the drone 1A is in the restrained state, air can be automatically discharged from the inside of the cushioning member 11 to separate the drone 1A from the restrained state by the obstacle B.

The restraint determination unit 25 determines the restraint state of the drone 1A when the internal pressure of the cushioning member 11 detected by the pressure sensor 26 exceeds a preset threshold value for a predetermined time. This is because even if the cushioning member 11 of the drone 1A simply collides with an obstacle B or the like, the internal pressure of the cushioning member 11 temporarily rises, so that the cushioning member 11 is buffered in order to distinguish between a restrained state and a mere collision. When the state in which the internal pressure of the member 11 exceeds the preset threshold value is maintained for a predetermined time, it is determined that the drone 1A is in the restrained state. The "predetermined time" can be several seconds, for example, 2-3 seconds.

In the second embodiment described above, the restrained state of the drone 1A is determined by detecting the internal pressure of the cushioning member 11 by the pressure sensor 26, but the tension acting on the cushioning member 11 instead of the pressure sensor 26 is determined. A tension sensor for detection can also be used.
When the internal pressure of the cushioning member 11 increases, the tension of the cushioning member 11 made of a flexible tubular body also increases, and when the internal pressure of the cushioning member 11 decreases, the tension of the cushioning member 11 also decreases. Therefore, even if the tension acting on the cushioning member 11 detected by the tension sensor exceeds a preset threshold value over a predetermined time, the restraint determination unit 25 determines that the drone 1A is in the restraint state. It becomes possible to do.

In the above-described first and second embodiments, air is enclosed in the cushioning member 11, but the present invention is not limited to this, and a gas other than air can be enclosed in the cushioning member 11. For example, an inert gas such as nitrogen can be used.
However, when the air pump 17 used as the gas discharge mechanism also fills the inside of the cushioning member 11 with gas, the outside air enters the inside of the cushioning member 11, so that the cushioning member 11 Air is preferable as the gas enclosed therein.

In the drone 1 according to the first embodiment shown in FIG. 2, the pressure sensor 26 for detecting the internal pressure of the cushioning member 11 is arranged in the cushioning member deforming portion 12, and the drone main body 3 and the cushioning member deforming portion 12 are arranged. The internal pressure of the cushioning member 11 that is electrically connected and detected by the pressure sensor 26 is transmitted from the wireless communication unit 15 of the drone main body 3 to the operation panel 21, and the operator can use the operation panel 21 to transmit the internal pressure of the cushioning member 11 to the operation panel 21. It can also be configured so that the internal pressure can be grasped.
In this way, the operator detects that the drone 1 is in the restrained state based on the internal pressure of the cushioning member 11, transmits a radio signal from the radio signal transmitter 22 to the drone 1, and transmits the cushioning member. The wireless switch 19 of the deforming portion 12 is turned on, and air can be discharged from the inside of the cushioning member 11.

Embodiment 3
In the drone restraint state release device 2 according to the first embodiment, as shown in FIG. 1, one annular cushioning member 11 is arranged on the outer peripheral portion of the guard frame 4 of the drone 1. , Not limited to this.

FIG. 7 is a perspective view showing a drone 31 provided with the drone restraint state release device 32 according to the third embodiment.
The drone 31 has a drone restraint state release device 32 instead of the drone restraint state release device 2 in the drone 1 according to the first embodiment, and has a drone body 3 and a polyhedral guard that surrounds the entire drone body 3. The frame 4 is the same as that used in the first embodiment.
The drone restraint state release device 32 has a cushioning member 33 arranged on the outer peripheral portion of the guard frame 4 and a cushioning member deforming portion 12 attached to the inside of the guard frame 4.

The cushioning member 33 is formed of three flexible annular tubular bodies 33A, 33B and 33C arranged on the outer peripheral portion of the guard frame 4. The three annular tubular bodies have a tubular body 33A extending along the XY plane, a tubular body 33B extending along the XZ plane, and a YZ, for example, when the XYZ coordinates are defined as shown in FIG. It consists of a tubular body 33C extending along a surface, and these three tubular bodies 33A, 33B and 33C are connected at intersections intersecting each other, and their respective interiors communicate with each other to form one internal space.
The cushioning member deforming portion 12 is the same as the cushioning member deforming portion 12 in the first embodiment shown in FIG. 2, and the air pump 17 provided in the cushioning member deforming portion 12 is connected to the internal space of the cushioning member 33. There is.

When the drone 31 is in the restrained state, the operator transmits a wireless signal from the wireless signal transmitter 22 to the drone 31, the wireless switch 19 of the cushioning member deforming portion 12 is turned on, and the drive control unit 18 sets the air pump 17 to the air pump 17. By driving, air is discharged from the inside of the cushioning member 33. As a result, the cushioning member 33 is deformed and the drone 31 can be released from the restrained state.
In the third embodiment, since the cushioning member 33 composed of the three annular tubular bodies 33A, 33B and 33C is arranged on the outer peripheral portion of the guard frame 4, at least one of the tubular bodies 33A, 33B and 33C Even when the drone 31 is restrained by contacting an obstacle, it is possible to release the restrained state.

The annular tubular body constituting the cushioning member 33 is not limited to three, and two or four or more annular tubular bodies may be connected to form the cushioning member.

Further, in the third embodiment, the cushioning member deforming portion 12A in the second embodiment shown in FIG. 6 can be used instead of the cushioning member deforming portion 12. In this case, the air pump 17 and the pressure sensor 26 of the cushioning member deforming portion 12A are connected to the internal space of the cushioning member 33 composed of the three annular tubular bodies 33A, 33B and 33C. As a result, when the drone 31 is in the restrained state, air can be automatically discharged from the inside of the cushioning member 33 to separate the drone 31 from the restrained state.

Embodiment 4
In the first embodiment described above, one annular cushioning member 11 is arranged on the outer peripheral portion of the guard frame 4 of the drone 1, and in the third embodiment, three are arranged on the outer peripheral portion of the guard frame 4 of the drone 31. The cushioning member 33 composed of the annular tubular bodies 33A, 33B and 33C is arranged, but the present invention is not limited to this.
FIG. 8 is a partial plan view showing a cushioning member 43 of the drone 41 provided with the drone restraint state release device 42 according to the fourth embodiment.
The drone 41 has the same drone body 3 and guard frame 4 as those used in the first embodiment, and as shown in FIG. 8, the plurality of beam members 9 constituting the guard frame 4 A plurality of flexible tubular bodies 43A are arranged on the outside, and by connecting the plurality of tubular bodies 43A to each other, a cushioning member 43 having one internal space is formed.

If the air pump 17 of the cushioning member deforming portion 12 according to the first embodiment shown in FIG. 2 is connected to the cushioning member 43, the operator transmits a wireless signal from the wireless signal transmitter 22 to the inside of the cushioning member 43. The drone restraint state release device 42 that discharges air from the drone 41 to release the restraint state of the drone 41 can be configured.
Further, if the air pump 17 and the pressure sensor 26 of the cushioning member deforming portion 12A according to the second embodiment shown in FIG. 6 are connected to the cushioning member 43, the cushioning member is automatically set when the drone 41 is in a restrained state. A drone restraint state release device 42 that discharges air from the inside of the 43 to release the restraint state of the drone 41 can be configured.

Since the cushioning member 43 in the fourth embodiment is formed of a plurality of tubular bodies 43A respectively arranged on the outside of the plurality of beam members 9 constituting the guard frame 4, how the drone 41 deals with obstacles. Even when the restraint is made in any direction, the restrained state can be released by discharging the air from the inside of the cushioning member 43.

Further, a plurality of flexible tubular bodies or spheres are arranged outside the plurality of beam members 9 constituting the polyhedral guard frame 4 in a state of being separated from each other, and the plurality of tubular bodies or spheres are arranged. A cushioning member can also be configured by the body. In this case, each of the plurality of tubular bodies or spherical bodies constituting the cushioning member has the same configuration as the cushioning member deforming portion 12 in the first embodiment shown in FIG. 2 or the cushioning in the second embodiment shown in FIG. By connecting the cushioning member deforming portion having the same configuration as the member deforming portion 12A, when the drone is restrained by an obstacle, air is discharged from the tubular body or the spherical body to separate the drone from the restrained state. Can be done.

Embodiment 5
The drone 1 in the above embodiment 1 includes, but is not limited to, a polyhedral guard frame 4 that surrounds the entire drone body 3.
FIG. 9 shows a drone 51 provided with the drone restraint state release device 52 according to the fifth embodiment. The drone 51 includes a drone main body 3 including a plurality of rotary wings (propellers) 7, and a plurality of ring-shaped guard frames 54 that surround the plurality of rotary wings 7 that are a part of the drone main body 3. The drone main body 3 has the same configuration as that used for the drone 1 in the first embodiment shown in FIG. Each guard frame 54 forms a so-called propeller guard that has rigidity and protects the corresponding rotor blade 7.

The drone restraint state release device 52 has a cushioning member 53 composed of a plurality of flexible annular tubular bodies 53A that surround the outer peripheral portions of the plurality of guard frames 54 and are arranged separately from each other. ing. Further, the drone restraint state release device 52 has a cushioning member deforming portion (not shown) connected to each of a plurality of tubular bodies 53A constituting the cushioning member 53. This cushioning member deforming portion has the same configuration as the cushioning member deforming portion 12 in the first embodiment shown in FIG.

As described above, even if the cushioning member 53 composed of the plurality of tubular bodies 53A is used, the operator is shown in FIG. 2 when the drone 51 is in a restrained state due to the cushioning member 53 being pinched by an obstacle or the like. By transmitting a wireless signal from the wireless signal transmitter 22, air is blown from the inside of the corresponding tubular body 53A by the air pump 17 of the cushioning member deformed portion (not shown) connected to each of the plurality of tubular bodies 53A constituting the cushioning member 53. Can be discharged. As a result, the plurality of tubular bodies 53A can be deformed to release the drone 51 from the restrained state.

Further, the cushioning member deforming portion (not shown) connected to each of the plurality of tubular bodies 53A constituting the cushioning member 53 may have the same configuration as the cushioning member deforming portion 12A in the second embodiment shown in FIG. .. In this case, the internal pressures of the plurality of tubular bodies 53A are detected by the pressure sensors 26 of the corresponding cushioning member deformation portions, respectively. Therefore, when the drone 51 is in the restrained state, among the plurality of tubular bodies 53A, the tubular body 53A in which the internal pressure detected by the pressure sensor 26 exceeds a preset threshold value for a predetermined time. Air is automatically discharged by the air pump 17 only to the drone 51, and the drone 51 is released from the restrained state.

In this way, the present invention can be applied to the drone 51 provided with the guard frame 54 forming the so-called propeller guard, and the drone 51 restrained by the obstacle can be released from the restrained state. ..
Although four rotor blades 7 are shown in FIG. 9, the number of rotor blades 7 is not limited to four, and the outer peripheral portion of the guard frame 54 of the rotor blade 7 corresponds to each rotor blade 7. The number of rotary blades 7 may be three or five or more as long as the tubular body 53A surrounding the tubular body 53A and the cushioning member deforming portion connected to the tubular body 53A are provided.

Embodiment 6
In the drone 51 according to the fifth embodiment, the cushioning member 53 is composed of a plurality of tubular bodies 53A that surround the outer peripheral portions of the guard frames 54 of the plurality of rotary wings 7 and are arranged separately from each other. For example, as in the drone restraint state release device 62 of the drone 61 shown in FIG. 10, the cushioning member 63 can be formed by one tubular body 63A that surrounds the entire guard frame 54 of the plurality of rotor blades 7.

In this case, since the cushioning member 63 is formed of one tubular body 63A, one cushioning member deforming portion (not shown) may be connected to the cushioning member 63. The cushioning member deforming portion may have the same configuration as the cushioning member deforming portion 12 in the first embodiment shown in FIG. 2 or the same configuration as the cushioning member deforming portion 12A in the second embodiment shown in FIG. ..
Even with such a configuration, when the drone 61 is in a restrained state due to the cushioning member 63 being pinched by an obstacle or the like, air can be discharged from the inside of the cushioning member 63 to separate the drone 61 from the restrained state. It will be possible.

In the drones 1, 1A, 31, 41, 51, 61 in the above-described embodiments 1 to 6, the cushioning members 11, 33 are outside the rigid guard frames 4, 54 that surround the entire or part of the drone body 3. , 43, 53, 63 are arranged, but do not necessarily require the guard frames 4, 54, and the cushioning members 11, 33, 43, arranged so as to surround all or a part of the drone body 3. The 53 and 63 can also have a guard frame function for protecting the drone body 3.
However, since the cushioning members 11, 33, 43, 53, 63 are flexible and deform according to the filling and discharging of gas, the cushioning members 11, 33, 43 are combined with the rigid guard frames 4, 54. , 53, 63 are preferably attached.

In the above embodiments 1 to 6, drones 1, 1A, 31, 41, 51 and 61 that fly by rotating the rotor 7 are exemplified, but the type of the drone utilizes the rotor. Not limited to. For example, even for a so-called balloon-type drone that fills the inside of a balloon with helium gas and flies, by arranging a cushioning member that can be deformed according to the filling and discharging of the gas on the outer peripheral portion of the balloon. The invention can be applied.

1,1A, 31,41,51,61 Drone, 2,2A,32,42,52,62 Drone restraint state release device, 3 Drone body, 4,54 guard frame, 5 housing, 6 motors, 7 rotary wings, 8 Camera, 9 Beam member, 11, 33, 43, 53, 63 Cushion member, 12, 12A Cushion member deformation part, 13 Flight control unit, 14 Imaging control unit, 15, 23 Wireless communication unit, 16, 20 Battery, 17 Air pump, 18 drive control unit, 19 wireless switch, 21 operation panel, 22 wireless signal transmitter, 24 operation unit, 25 restraint judgment unit, 26 pressure sensor, 33A, 33B, 33C, 43A, 53A, 63A tubular body, D1 diameter , D2, D3 outer diameter, B obstacle, P columnar member, W1 spacing.

Claims (10)

A device that removes a drone restrained by an obstacle from the restrained state.
A cushioning member arranged on the outer peripheral portion of the drone and deformable according to the filling and discharging of gas.
A gas discharge mechanism for discharging the gas from the inside of the shock absorber, and
A drone restraint state release device including a drive control unit that deforms the cushioning member by driving the gas discharge mechanism. Equipped with a wireless switch that receives a wireless signal and turns it on or off.
The drone restraint state release device according to claim 1, wherein the drive control unit drives the gas discharge mechanism when the wireless switch is in the ON state. It is equipped with a restraint detection unit that detects that the drone is in a restraint state.
The drone restraint state release device according to claim 1, wherein the drive control unit drives the gas discharge mechanism when the restraint detection unit detects that the drone is in the restraint state. The restraint detection unit is
A pressure sensor that detects the internal pressure of the shock absorber and
3. The third aspect of the present invention includes a restraint determination unit that determines that the drone is in a restraint state when the internal pressure of the shock absorber detected by the pressure sensor exceeds a preset threshold value for a predetermined time. The described drone restraint state release device. The restraint detection unit is
A tension sensor that detects the tension acting on the cushioning member, and
The drone restraint according to claim 3, further comprising a restraint determination unit that determines that the drone is in a restraint state when the tension detected by the tension sensor exceeds a preset threshold value over a predetermined time. State release device. The drone restraint state release device according to any one of claims 1 to 5, wherein the cushioning member is made of an electrically insulating material. The drone restraint state release device according to any one of claims 1 to 6, wherein the gas discharge mechanism comprises an air pump or a suction fan. The drone
The drone body for unmanned flight and
Including a guard frame that surrounds all or part of the drone body,
The drone restraint state release device according to any one of claims 1 to 7, wherein the cushioning member is mounted on the guard frame. A drone provided with the drone restraint state release device according to any one of claims 1 to 8. It is a method of providing a cushioning member that can be deformed according to the filling and discharging of gas on the outer periphery and releasing the drone restrained by an obstacle from the restrained state.
A method for releasing a drone from a restrained state, comprising a step of releasing the drone from the restrained state by discharging the gas from the inside of the cushioning member and deforming the cushioning member.

Images