JP2020200704A - Waterway tunnel inspection device and control method of waterway tunnel inspection device - Google Patents

Abstract

To improve flight stability of a waterway tunnel inspection device.SOLUTION: A waterway tunnel inspection device configured to fly inside a waterway tunnel comprises a balloon filled with a gas whose specific gravity is lighter than that of air, a thrust generation mechanism that is mounted on a balloon and generates thrust, and a controller that controls the thrust generation mechanism. The control of the thrust generation mechanism comprises a first control that generates thrust to turn a reference axis set in the waterway tunnel inspection device in the horizontal plane, and a second control that generates a thrust that is in the horizontal plane and moves the waterway tunnel inspection device in a direction perpendicular to the reference axis. The controller is configured to prioritize the first control without the second control if a tilt angle of the reference axis with respect to the stretching direction of the waterway tunnel is out of the specified range, and to perform the second control if the tilt angle is within the specified range.SELECTED DRAWING: Figure 9

Description

The present invention relates to a waterway tunnel inspection device and a control method thereof.

Many waterways have been constructed and are in service for water use, irrigation and other purposes. Some canals are built underground, that is, as canal tunnels (groundwater canals).

There is a request to inspect such canal tunnels. Since the canal tunnel can deteriorate over time, it is desirable to regularly inspect the condition of the canal tunnel for safe and stable operation of the canal tunnel. In particular, in the event of a large earthquake, it is desirable to inspect the walls of the canal tunnel to confirm the soundness of the canal tunnel.

The applicant of this application has previously filed a patent application for a waterway tunnel inspection device for inspecting the wall surface of the waterway tunnel (see JP-A-2018-199915). This patent application discloses a waterway tunnel inspection device in which an observation system and a controller are mounted on a balloon (envelope) to inspect a wall surface while autonomously flying inside the waterway tunnel.

It is desirable that such a waterway tunnel inspection device can fly stably inside the waterway tunnel. Winds are often blown inside channel tunnels, which can destabilize the flight of channel tunnel inspection equipment. If the flight is unstable, the channel tunnel inspection device may collide with the wall surface of the channel tunnel.

JP-A-2018-199915

Therefore, one of the objects of the present invention is to provide a technique for improving the flight stability of the waterway tunnel inspection device. Other objects and novel features of the invention will be appreciated by those skilled in the art from the disclosure below.

From one aspect of the present invention, a waterway tunnel inspection device configured to fly inside a waterway tunnel is mounted on a balloon filled with a gas having a specific gravity lighter than that of air and the balloon to generate thrust. It includes a thrust generation mechanism and a controller that controls the thrust generation mechanism. The control of the thrust generation mechanism includes the first control of generating a thrust for turning the reference axis set in the water channel tunnel inspection device in the horizontal plane, and the water channel in the horizontal plane in the direction perpendicular to the reference axis. It includes a second control that generates thrust to move the tunnel inspection device. When the inclination angle of the reference axis with respect to the extension direction of the waterway tunnel is out of the specified range, the controller preferentially performs the first control without performing the second control, and the inclination angle is the specified. When it is within the range, it is configured to perform the second control.

Another aspect of the present invention provides a control method for a channel tunnel inspection device comprising a balloon filled with a gas having a specific gravity lighter than that of air and configured to fly inside the channel tunnel. The control method includes a first control for generating a thrust for turning a reference axis set in the water channel tunnel inspection device in a horizontal plane, and the water channel tunnel inspection device in a direction in the horizontal plane and perpendicular to the reference axis. Includes a step of selectively performing a second control that generates thrust to move the. When the inclination angle of the reference axis with respect to the extension direction of the waterway tunnel is out of the specified range, the first control is preferentially performed without performing the second control, and the inclination angle is within the specified range. In this case, the second control is performed.

According to the present invention, a technique for improving the flight stability of a waterway tunnel inspection device is provided.

It is a side view which shows the structure of the waterway tunnel inspection system and the waterway tunnel inspection device used by the waterway tunnel inspection system in one embodiment. It is a side view which shows the structure of the airframe of the waterway tunnel inspection apparatus in one Embodiment. It is a side view which shows the structure of the frame in one Embodiment. It is a front view which shows the structure of the frame in one Embodiment. It is a side view which shows the structure of the frame and each frame bar in one Embodiment. It is a block diagram which shows the system structure of the waterway tunnel inspection apparatus in one Embodiment. It is a figure explaining the horizontal thrust control in one Embodiment. It is a figure explaining the vertical thrust control in one Embodiment. It is a flowchart which shows the horizontal thrust control in one Embodiment. It is a flowchart which shows the distance control in one Embodiment. In one embodiment, it is a graph which shows the rotation speed command set by the distance control.

In one embodiment, as shown in FIG. 1, the waterway tunnel inspection system 100 includes a waterway tunnel inspection device 1 and a monitor terminal 2. In the following description, the XYZ Cartesian coordinate system in which the X-axis is defined in the lateral direction of the waterway tunnel inspection device 1, the Y-axis is defined in the front-rear direction, and the Z-axis is defined in the vertical direction represents the direction. May be used for.

The waterway tunnel inspection device 1 is configured as an airship, and is configured to fly inside the waterway tunnel and inspect the wall surface. In one embodiment, the canal tunnel is an underground canal. The waterway tunnel inspection device 1 is configured to fly inside the waterway tunnel and acquire information on the condition of the wall surface of the waterway tunnel. In one embodiment, the waterway tunnel inspection device 1 is configured to take a picture of the wall surface of the waterway tunnel while flying inside the waterway tunnel and acquire a photographed image.

The monitor terminal 2 is used to remotely control the waterway tunnel inspection device 1. In addition, the monitor terminal 2 is configured to display information regarding the state of the wall surface of the waterway tunnel acquired by the waterway tunnel inspection device 1. In one embodiment, the monitor terminal 2 is configured to display a photographed image of the wall surface of the waterway tunnel obtained by the waterway tunnel inspection device 1 on the display unit 2a.

In one embodiment, the waterway tunnel inspection device 1 includes a balloon 3, an airframe 4, a main thruster 5, and a wall surface information acquisition device 6. A gas lighter than air, for example, helium, is sealed inside the balloon 3, and the waterway tunnel inspection device 1 flies by utilizing the buoyancy obtained by the balloon 3. The balloon 3 has a long shape in the front-rear direction of the waterway tunnel inspection device 1, and in the Y-axis direction in FIG. The aircraft 4, the main thruster 5, and the wall surface information acquisition device 6 are all mounted on the balloon 3. The machine body 4 is joined to the lower part of the balloon 3. The main thruster 5 is joined to one end of the balloon 3 in the front-rear direction, and the wall surface information acquisition device 6 is joined to the other end. The main thruster 5 is configured to generate thrust in the front-rear direction of the waterway tunnel inspection device 1. The wall surface information acquisition device 6 is configured to acquire information regarding the state of the wall surface of the waterway tunnel. In one embodiment, the wall surface information acquisition device 6 photographs the wall surface of the waterway tunnel and acquires a photographed image.

As illustrated in FIG. 2, in one embodiment, the airframe 4 includes a support 11, side thrusters 12, 13, vertical thrusters 14, 15, and a main unit 16.

The support 11 supports the side thrusters 12 and 13, the vertical thrusters 14 and 15, and the main unit 16. A receiver 17 is provided on the support 11, and the machine body 4 is joined to the balloon 3 by the receiver 17.

The side thrusters 12 and 13 and the vertical thrusters 14 and 15 together with the above-mentioned main thruster 5 constitute a thrust generation mechanism for generating thrust. The side thrusters 12 and 13 are configured to generate thrust in the lateral direction of the waterway tunnel inspection device 1, in the + X direction or the −X direction in FIG. The side thrusters 12 and 13 are used to generate a thrust for moving the channel tunnel inspection device 1 in parallel in the lateral direction and for generating a thrust for turning the channel tunnel inspection device 1 in a horizontal plane. The directions in which the side thrusters 12 and 13 generate thrust are not always the same. For example, when the channel tunnel inspection device 1 is swiveled in a horizontal plane, one of the side thrusters 12 and 13 generates a thrust in the + X direction, and the other generates a thrust in the −X direction.

On the other hand, the vertical thrusters 14 and 15 are configured to generate thrust in the vertical direction (direction perpendicular to the horizontal plane), and in FIG. 2, in the + Z direction or the −Z direction. The vertical thrusters 14 and 15 are used to generate thrust for controlling the height of the waterway tunnel inspection device 1 from the bottom surface of the waterway tunnel.

In one embodiment, side thrusters 12 and 13 are provided near both ends of the airframe 4, and vertical thrusters 14 and 15 and a main unit 16 are arranged between the side thrusters 12 and 13. Such an arrangement is useful for increasing the moment around the center of gravity of the waterway tunnel inspection device 1 that can be generated by the side thrusters 12 and 13 while suppressing the size of the airframe 4, and increasing the turning ability. Further, the main unit 16 is arranged between the vertical thrusters 14 and 15. Such an arrangement increases the distance between the vertical thrusters 14 and 15 while suppressing the size of the airframe 4, and enhances the stability of the waterway tunnel inspection device 1.

In one embodiment, the main unit 16 includes a controller 21, an RF interface 22, and a battery 23. The controller 21 controls each device of the waterway tunnel inspection device 1. The controller 21 is connected to the main thrusters 5, the side thrusters 12, 13 and the vertical thrusters 14, 15 via a wire harness 24, and is configured to control these thrusters. The RF interface 22 is used for wireless communication between the monitor terminal 2 and the controller 21. The battery 23 supplies electric power used for operating each device.

In one embodiment, the body 4 further includes a front lateral distance sensor 25, a rear lateral distance sensor 26, and a vertical distance sensor 27.

The front lateral distance sensor 25 and the rear lateral distance sensor 26 measure the distance to the wall surface of the waterway tunnel in the lateral direction of the waterway tunnel inspection device 1. The front lateral distance sensor 25 and the rear lateral distance sensor 26 are arranged at positions displaced in the front-rear direction, and measure the lateral distance to the wall surface of the waterway tunnel at the two positions displaced in the front-rear direction. .. As will be described later, the distance measured by the front lateral distance sensor 25 and the rear lateral distance sensor 26 is used to detect the orientation of the waterway tunnel inspection device 1, and further controls the side thrusters 12 and 13. Used. In one embodiment, laser sensors are used as the front lateral distance sensor 25 and the rear lateral distance sensor 26. The use of a laser sensor is effective in improving the measurement accuracy of the distance to the wall surface.

The vertical distance sensor 27 measures the distance from the channel tunnel inspection device 1 to the bottom surface of the channel tunnel, that is, the height from the bottom surface in the vertical direction. The measured height is used to control the vertical thrusters 14 and 15. In one embodiment, the ultrasonic sensor is used as the vertical distance sensor 27. It is assumed that water collects on the bottom surface of the channel tunnel, and the use of ultrasonic sensors is effective in making it possible to measure the height from the bottom surface in such a situation.

The balloon 3 is required to have a certain level of strength in order to maintain its shape. For example, when a laminated film in which a metal film and a resin layer are laminated is used for a balloon in order to suppress leakage of the enclosed gas, securing the strength of the balloon 3 can be a problem.

In one embodiment, as shown in FIG. 3, a frame 51 for reinforcing the balloon 3 and a belt 52 for fixing the balloon 3 to the frame 51 may be used. With the balloon 3 housed in the frame 51, the belt 52 is wound around the balloon 3 and the frame 51, so that the balloon 3 is coupled to the frame 51.

In one embodiment, the frame 51 includes a front joint 53, a rear joint 54, and a plurality of frame bars 55. The frame bar 55 is a member for positioning the balloon 3, and is provided so as to extend in the front-rear direction of the waterway tunnel inspection device 1 as a whole. Although four frame bars 55 are shown in FIG. 3, a frame bar 55 (not shown) hidden behind the balloon 3 may be provided. In one embodiment, as shown in FIG. 4, six frame bars 55 may be provided, and the number of frame bars 55 can be changed in various ways. One end of each of the plurality of frame bars 55 is connected to the front joint 53, and the other end is connected to the rear joint 54. In one embodiment, the wall surface information acquisition device 6 is attached to the front joint 53 and the main thruster 5 is attached to the rear joint 54.

As shown in FIG. 5, in one embodiment, each frame bar 55 includes a front bar 55a, a rear bar 55b, and an intermediate bar 55c. One end of the front bar 55a is coupled to the front joint 53, and the other end is coupled to the first end of the intermediate bar 55c by the joint 55d. One end of the rear bar 55b is coupled to the rear joint 54, and the other end is coupled to the second end of the intermediate bar 55c by the joint 55e. In one embodiment, metal pipes may be used as the front bar 55a, the rear bar 55b, and the intermediate bar 55c.

When the balloon 3 is attached to the frame 51, in one embodiment, as shown in FIG. 4, the frame bar 55 is arranged apart from each other around the axis connecting the front joint 53 and the rear joint 54, and this state. Then, the balloon 3 is housed in the frame 51. Preferably, the balloon 3 is housed in the frame 51 with the frame bars 55 arranged at equal angular intervals. The belt 52 is wound around the balloon 3 and the frame 51 with the balloon 3 housed in the frame 51. Such a structure is effective for reinforcing the balloon 3.

FIG. 6 shows the system configuration of the waterway tunnel inspection device 1 in one embodiment. In one embodiment, the wall surface information acquisition device 6 includes a lighting device 28 that illuminates the wall surface of the waterway tunnel, and a camera 29 that photographs the wall surface of the waterway tunnel and acquires a photographed image. In one embodiment, an LED (light emitting diode) may be used as the light source of the lighting device 28. In one embodiment, a 360 ° camera may be used as the camera 29. The captured image acquired by the camera 29 is transmitted to the monitor terminal 2 via the RF interface 22, and is displayed on the display unit 2a of the monitor terminal 2. The captured image may be stored in the storage device 30 provided in the controller 21.

The main thruster 5 includes a rotor 31, a motor 32 that rotates the rotor 31, and an ESC (electronic speed controller) 33 that controls the motor 32. The ESC 33 controls the motor 32 so that the rotor 31 rotates at a rotation speed according to the rotation speed command received from the controller 21. In one embodiment, PWM (pulse width modulation) control is performed in the ESC 33, and a PWM value is supplied to the ESC 33 as a rotation speed command.

The side thrusters 12 and 13 include a pitch variable rotor 34 having a variable pitch angle, a motor 35 that rotates the pitch variable rotor 34, an ESC 36 that controls the motor 35, and a servomotor 37. The ESC 36 controls the motor 35 so that the pitch variable rotor 34 rotates at a rotation speed corresponding to the rotation speed command received from the controller 21. In one embodiment, PWM control is performed on the ESC 36, and a PWM value is supplied to the ESC 36 as a rotation speed command. The servomotor 37 controls the blades of the pitch variable rotor 34 to a desired pitch angle by rotating the blades of the pitch variable rotor 34 around a rotation axis extending in the blade width direction under the control of the controller 21.

The vertical thrusters 14 and 15 include a rotor 38, a motor 39 that rotates the rotor 38, and an ESC 40 that controls the motor 39. The ESC 40 controls the motor 39 so that the rotor 38 rotates at a rotation speed according to the rotation speed command received from the controller 21. In one embodiment, PWM control is performed on the ESC 40, and a PWM value is supplied to the ESC 40 as a rotation speed command.

The operation of the waterway tunnel inspection device 1 will be described below.
In one embodiment, the waterway tunnel inspection device 1 has two operation modes, a manual operation mode and an autonomous flight mode. In the manual operation mode, the waterway tunnel inspection device 1 flies according to the operation performed by the monitor terminal 2. In the autonomous flight mode, the channel tunnel inspection device 1 collects information about the wall surface of the channel tunnel while flying autonomously.

In the autonomous flight mode, the channel tunnel inspection device 1 controls the thrust generated by the thrust generation mechanism composed of the main thrusters 5, the side thrusters 12, 13 and the vertical thrusters 14, 15 by the controller 21 mounted on the main thruster 21. .. Thrust control is performed so that the waterway tunnel inspection device 1 does not collide with the wall surface.

With reference to FIG. 7, in one embodiment, horizontal thrust control is performed to control the thrusts f _{F and} f _R generated by the side thrusters 12 and 13, respectively. Note that FIG. 7 (and FIG. 8) illustrates the xyz Cartesian coordinate system defined for the channel tunnel 200. In this xyz orthogonal coordinate system, the x-axis is defined in the width direction of the waterway tunnel 200, the y-axis is defined in the extension direction, and the z-axis is defined in the height direction.

In one embodiment, the horizontal thrust control is performed based on the reference axis 1a and the reference point 1b defined in the channel tunnel inspection device 1. In one embodiment, the reference axis 1a is defined to be parallel to the horizontal plane and parallel to the anteroposterior direction of the channel tunnel inspection device 1, and the reference point 1b is defined above the reference axis 1a. In one embodiment, the front lateral distance sensor 25 and the rear lateral distance sensor 26 are provided at different positions along the reference axis 1a, and are located between the front lateral distance sensor 25 and the rear lateral distance sensor 26. The distance is 2L. In one embodiment, the reference point 1b is defined at a position where both the distance from the front lateral distance sensor 25 and the distance from the rear lateral distance sensor 26 are L.

In one embodiment, the thrusts f _{F and} f _R generated by the side thrusters 12 and 13, respectively _, are controlled so that the inclination angle θ with respect to the extension direction of the water channel tunnel 200 of the reference axis 1a is within the specified range. In FIG. 7, the sign of the tilt angle θ is defined so that the counterclockwise direction is positive. The tilt angle θ is controlled by generating thrusts f _{F and} f _R in opposite directions by the side thrusters 12 and 13 to rotate the channel tunnel inspection device 1 in the horizontal plane.

In one embodiment, the distance δ to the wall surface 200a of the waterway tunnel 200 of the waterway tunnel inspection device 1 is further defined by using the reference point 1b, and the side thrusters 12 and 13 are set so that the distance δ is within the specified range. The thrusts f _{F and} f _R generated, respectively _, are controlled. To control the distance δ, the side thrusters 12 and 13 generate thrusts f _{F and} f _R in the same direction to move the channel tunnel inspection device 1 in the horizontal direction (that is, in the horizontal plane and perpendicular to the reference axis 1a). It is done by letting.

In one embodiment, the tilt angle θ is calculated based on the sensor values δ _F and δ _R acquired by the front lateral distance sensor 25 and the rear lateral distance sensor 26, and the distance δ is calculated based on the tilt angle θ. Will be done. Here, the sensor value δ _F corresponds to the distance from the position (first position) where the front lateral distance sensor 25 is provided on the reference axis 1a to the wall surface 200a of the waterway tunnel 200. Further, the sensor value δ _R corresponds to the distance from the position (second position) where the rear lateral distance sensor 26 is provided on the reference axis 1a to the wall surface 200a of the waterway tunnel 200.

In one embodiment, the tilt angle θ and the distance δ are calculated according to the following equations (1) and (2).

Referring to FIG. 8, in one embodiment, the vertical thrust control for controlling the thrust f _Z where vertical thrusters 14, 15 are generated is performed. In one embodiment, the thrust f _Z generated by the vertical thrusters 14 and 15 is controlled based on the sensor value δ _Z acquired by the vertical distance sensor 27. The sensor value δ _Z corresponds to the height from the bottom surface of the waterway tunnel 200 of the waterway tunnel inspection device 1. In one embodiment, as the height is within the specified range, the thrust f _Z where vertical thrusters 14, 15 is generated is controlled.

It is desired that the waterway tunnel inspection device 1 can stably fly inside the waterway tunnel 200, but in reality, various events that impair the stability of flight may occur. For example, the wind blowing inside the waterway tunnel 200 can destabilize the flight of the waterway tunnel inspection device 1. If the flight is unstable, the waterway tunnel inspection device 1 may collide with the wall surface of the waterway tunnel.

With reference to FIG. 7 again, in one embodiment, for stable flight of the channel tunnel inspection device 1, the tilt angle θ is preferentially controlled and the tilt angle θ is within the specified range. The control for adjusting the distance δ is performed in the horizontal thrust control. Such control may be referred to as "angle priority control" below. In one embodiment, when the inclination angle θ is out of the specified range, the first control for turning the reference axis 1a in the horizontal plane is preferentially performed, and the waterway tunnel is not provided until the inclination angle θ is within the specified range. The second control for moving the inspection device 1 in the horizontal direction (+ X direction or −X direction) is performed. If the tilt angle θ is out of the specified range, the second control is not performed.

The angle priority control stabilizes the attitude of the waterway tunnel inspection device 1, thereby contributing to the stabilization of the flight of the waterway tunnel inspection device 1. In horizontal thrust control, for example, when a disturbance due to wind occurs, the front lateral distance sensor 25 and the rear lateral distance sensor 26 detect a change in distance until the side thrusters 12 and 13 are controlled. It takes time, and during that time, the motion state of the waterway tunnel inspection device 1 may change. This can cause flight instability. By performing the angle priority control, the attitude of the waterway tunnel inspection device 1, that is, the inclination angle θ is controlled to some extent stably, and thus the fluctuation of the distance δ can be reduced. This is suitable for preventing a collision with the wall surface of the waterway tunnel inspection device 1.

The use of the variable pitch rotor 34 for the side thrusters 12 and 13 (see FIG. 6) is effective in reducing the delay in the control of the side thrusters 12 and 13 and further stabilizing the flight of the channel tunnel inspection device 1. .. In one embodiment, the directions of the thrusts f _{F and} f _R generated by the side thrusters 12 and 13 are switched by controlling the pitch angle without changing the rotation direction of the pitch variable rotor 34. In one embodiment, the variable pitch rotor 34 is configured to have a pitch angle that generates thrust in the + X direction and a pitch angle that generates thrust in the −X direction. Generally, the thrust direction of the thruster can be switched by reversing the rotation direction, but there is a certain delay in reversing the rotation direction. Therefore, if the thrust directions of the side thrusters 12 and 13 are switched by reversing the rotation direction, the delay in the control of the side thrusters 12 and 13 increases. This can reduce flight stability. By switching the thrust direction by switching the pitch angle, it is possible to reduce the delay in the control of the side thrusters 12 and 13 and improve the flight stability.

In one embodiment, the pitch angle of the variable pitch rotor 34 is the first pitch angle where thrust is generated in the + X direction, the second pitch angle where thrust is generated in the −X direction, and the third pitch angle where thrust is not generated. Selected from among. In one embodiment, the third pitch angle at which thrust is not generated is defined as 0. In this case, the pitch angle of the pitch variable rotor 34 is the first pitch angle Φ _fix where thrust is generated in the + X direction and the thrust in the −X direction. It may be selected from the second pitch angle −Φ _fix in which the thrust is generated and the third pitch angle 0 in which the thrust is not generated. When a desired pitch angle is selected by the controller 21 from the first to third pitch angles and a pitch angle command for designating the pitch angle is supplied to the servomotors 37 of the side thrusters 12 and 13, each servo The motor 37 controls the pitch variable rotor 34 to the pitch angle specified in the pitch angle command. According to such control, the magnitude and direction of the thrust of the side thrusters 12 and 13 can be controlled by a simple algorithm.

In one embodiment, horizontal thrust control is performed in the procedure shown in FIG. Each step shown in FIG. 9 is performed under the control of the controller 21.

When the horizontal thrust control is started, the sensor values δ _F and δ _R are acquired by the front lateral distance sensor 25 and the rear lateral distance sensor 26 in step S01. As described above, the sensor value δ _F indicates the distance from the position where the front lateral distance sensor 25 is provided on the reference axis 1a to the wall surface 200a of the waterway tunnel 200, and the sensor value δ _R is , The distance from the position where the rear lateral distance sensor 26 is provided on the reference axis 1a to the wall surface 200a of the waterway tunnel 200 is shown.

In step S02, the tilt angle θ and the distance δ are calculated based on the sensor values δ _F and δ _R acquired in step S01. In one embodiment, the tilt angle θ is calculated according to the above equation (1), and the distance δ is calculated according to the above equation (2).

In step S03, it is determined whether the inclination angle θ is within the specified range. In one embodiment, the range of −θ ₁ ≦ θ ≦ θ ₁ is defined as the defined range, and it is determined whether the inclination angle θ is in the range of −θ ₁ ≦ θ ≦ θ ₁ .

When it is determined that the tilt angle θ is not within the specified range, in other words, when the tilt angle θ is greatly tilted from the extending direction of the waterway tunnel 200, the tilt angle control is preferentially performed in step S04. In the tilt angle control, the channel tunnel inspection device 1 is used according to the sign of the tilt angle θ, that is, whether the reference axis 1a is tilted clockwise or counterclockwise with respect to the extension direction of the channel tunnel 200. The rotation speed command and pitch angle command of the side thrusters 12 and 13 are generated so as to rotate the side thrusters 12 and 13 counterclockwise or clockwise. In one embodiment, if −θmax ≦ θ <−θ ₁ holds in step S11, a rotation speed command and a pitch angle command are generated so that the waterway tunnel inspection device 1 turns counterclockwise in step S13. If θ ₁ <θ _max ≦ θ _max holds in step S12, a rotation speed command and a pitch angle command are generated so that the waterway tunnel inspection device 1 turns clockwise in step S14.

The turning of the waterway tunnel inspection device 1 is performed by the side thrusters 12 and 13 generating thrust in opposite directions. When the waterway tunnel inspection device 1 is turned counterclockwise, a pitch angle command is issued so that the front side thruster 12 generates thrust in the −X direction and the rear side thruster 13 generates thrust in the + X direction. Will be generated. In one embodiment, the pitch angle command supplied to the side thruster 12 is set to the second pitch angle −Φ _fix that generates thrust in the −X direction, and the pitch angle command supplied to the side thruster 13 is set to the + X direction. It is set to the first pitch angle Φ _fix that generates thrust. At this time, the rotation speed command supplied to the side thrusters 12 and 13 is set to a predetermined value N _rot that generates a predetermined non-zero thrust.

On the other hand, when the waterway tunnel inspection device 1 is turned clockwise, a pitch angle command is given so that the front side thruster 12 generates thrust in the + X direction and the rear side thruster 13 generates thrust in the −X direction. Is generated. In one embodiment, the pitch angle command supplied to the side thruster 12 is set to the first pitch angle Φ _fix that generates thrust in the + X direction, and the pitch angle command supplied to the side thruster 13 is set to the −X direction. It is set to the second pitch angle −Φ _fix that generates thrust.

In one embodiment, if the reference axis 1a is excessively tilted, for example, if θ <−θ _max or θ _max <θ holds, an alarm is generated in step S15. In one embodiment, the generated alarm is output from the monitor terminal 2. The operator can switch the waterway tunnel inspection device 1 from the autonomous flight mode to the manual operation mode with reference to the output alarm and take an appropriate response.

If it is determined in step S03 that the inclination angle θ is within the specified range, and if −θ ₁ ≦ θ ≦ θ ₁ holds in one embodiment, the distance control is performed in step S05. In the distance control, the thrusts f _F and f _R generated by the side thrusters 12 and 13 are controlled so as to move the channel tunnel inspection device 1 in the horizontal plane in the direction perpendicular to the reference axis 1a. In one embodiment, in the distance control, the rotation speed command and the pitch angle command are set so that the side thrusters 12 and 13 generate the same thrust in the same direction, or the thrust is zero.

FIG. 10 shows an example of the procedure of the distance control, and FIG. 11 shows the relationship between the rotation speed command generated by the distance control shown in FIG. 10 and the distance δ. As shown in FIG. 10, in one embodiment, in steps S21 to S24, the range to which the distance δ calculated in step S02 belongs is determined, and the rotation speed command and the pitch angle command are set according to the range to which the distance δ belongs. Will be done.

In one embodiment, when it is determined in step S21 that the distance δ is smaller than δ ₁ , the rotation speed command is set to specify the maximum allowable rotation speed N _max in step S25, and the pitch angle is set. The command is set to a second pitch angle of -Φ _fix that generates thrust in the -X direction.

In one embodiment, when it is determined in step S22 that the distance δ is δ ₁ or more and smaller than δ ₂ , the rotation speed command is set by proportional control (P control) based on the distance δ in step S26, and the pitch is set. The angle command is set to the second pitch angle −Φ _fix that generates thrust in the −X direction. In one embodiment, as shown in FIG. 11, the rotation speed command is linearly decreased from the rotation speed N _{max as the} distance δ increases.

In one embodiment, when it is determined in step S23 that the distance δ is δ ₂ or more and δ ₃ or less, in step S27, the rotation speed command and the pitch angle command are sent, and the thrust generated by the side thrusters 12 and 13 is zero. Is set to be. In one embodiment, the rotation speed command is set to specify zero rotation speed. At this time, in one embodiment, the pitch angle command may be set to the third pitch angle 0 that does not generate thrust.

In one embodiment, when it is determined in step S24 that the distance δ is greater than δ ₃ and less than or equal to δ ₄ , the rotation speed command is set by proportional control (P control) based on the distance δ in step S28. , The pitch angle command is set to the first pitch angle Φ _fix that generates thrust in the + X direction. In one embodiment, as shown in FIG. 11, the rotation speed command is linearly increased as the distance δ increases from the rotation speed 0.

In one embodiment, when it is determined in step S24 that the distance δ is larger than δ ₄ , the rotation speed command is set to specify the maximum allowable rotation speed N _max in step S29, and the pitch angle command is set. Is set to the first pitch angle Φ _fix that generates thrust in the + X direction.

According to the distance control shown in FIGS. 10 and 11, the rotation speed command and the pitch command supplied to the side thrusters 12 and 13 are set so that the distance δ is generally controlled in the range of δ ₂ to δ _3. Will be done.

Returning to FIG. 9, in step S06, the rotation speed command and the pitch angle command set by the tilt angle control in step S04 or the distance control in step S05 are output to the side thrusters 12 and 13. The ESC 36 of the side thrusters 12 and 13 rotates the pitch variable rotor 34 at the rotation speed specified by the rotation speed command, and the servomotor 37 designates the pitch variable rotor 34 of the side thrusters 12 and 13 by the pitch angle command. Set to the pitch angle.

Although the embodiments of the present invention are specifically described above, the present invention is not limited to the above embodiments. Those skilled in the art will appreciate that the present invention can be practiced with various modifications.

100: Waterway tunnel inspection system 1: Waterway tunnel inspection device 1a: Reference axis 1b: Reference point 2: Monitor terminal 2a: Display unit 3: Balloon 4: Aircraft 5: Main thruster 6: Wall surface information acquisition device 11: Support 12, 13: Side thrusters 14, 15: Vertical thrusters 16: Main unit 17: Receiver 21: Controller 22: RF interface 23: Battery 24: Wire harness 25: Front lateral distance sensor 26: Rear lateral distance sensor 27: Vertical direction Distance sensor 28: Lighting device 29: Camera 30: Storage device 31: Rotor 32: Motor 33: ESC
34: Variable pitch rotor 35: Motor 36: ESC
37: Servo motor 38: Rotor 39: Motor 40: ESC
51: Frame 52: Belt 53: Front joint 54: Rear joint 55: Frame bar 55a: Front bar 55b: Rear bar 55c: Intermediate bar 55d: Joint 55e: Joint 200: Waterway tunnel 200a: Wall surface

Claims (9)

A waterway tunnel inspection device configured to fly inside a waterway tunnel.
A balloon filled with a gas whose specific gravity is lighter than that of air,
A thrust generation mechanism mounted on the balloon to generate thrust,
It is equipped with a controller that controls the thrust generation mechanism.
The control of the thrust generation mechanism includes the first control of generating a thrust for turning the reference axis set in the water channel tunnel inspection device in the horizontal plane, and the water channel in the horizontal plane in the direction perpendicular to the reference axis. Including a second control that generates thrust to move the tunnel inspection device,
When the inclination angle of the reference axis with respect to the extension direction of the waterway tunnel is out of the specified range, the controller preferentially performs the first control without performing the second control, and the inclination angle is the specified. A channel tunnel inspection device configured to perform the second control when within range. The waterway tunnel inspection device according to claim 1.
The thrust generation mechanism
A first thruster that is in the horizontal plane and is configured to be capable of generating thrust in a first direction perpendicular to the reference axis and a second direction opposite to the first direction.
It is provided with a second thruster that is located offset from the first thruster in a direction parallel to the reference axis and is configured to be capable of generating thrust in the first direction and the second direction.
A waterway tunnel inspection device in which the first thruster and the second thruster are controlled by the first control and the second control. The waterway tunnel inspection device according to claim 2.
The first thruster and the second thruster include a first rotor and a second rotor, respectively.
The first rotor and the second rotor are configured so that the pitch angle is variable so that thrust can be generated in both the first direction and the second direction without changing the rotation direction. Tunnel inspection equipment. The waterway tunnel inspection device according to claim 3.
The controller sets the pitch angles of the first rotor and the second rotor to the first pitch angle that generates thrust in the first direction, the second pitch angle that does not generate thrust, and the thrust in the second direction. A channel tunnel inspection device configured to select from among the third pitch angles that generate. The waterway tunnel inspection apparatus according to any one of claims 2 to 4.
The thrust generation mechanism is further configured to generate thrust in a direction perpendicular to the horizontal plane, and includes a third thruster and a fourth thruster located offset in a direction parallel to the reference axis.
The first thruster, the second thruster, the third thruster, and the fourth thruster have the reference axis so that the third thruster and the fourth thruster are located between the first thruster and the second thruster. Waterway tunnel inspection equipment arranged side by side in the direction parallel to. The waterway tunnel inspection apparatus according to any one of claims 1 to 5.
In addition
A first distance sensor that acquires a first sensor value corresponding to a first distance from the first position on the reference axis to the wall surface of the waterway tunnel, and
A second distance sensor that acquires a second sensor value corresponding to a second distance from a second position different from the first position on the reference axis to the wall surface of the waterway tunnel is provided.
The controller is a waterway tunnel inspection device that specifies the inclination angle based on the first sensor value and the second sensor value. The waterway tunnel inspection apparatus according to any one of claims 1 to 5.
Further, an ultrasonic sensor for acquiring a third sensor value corresponding to a third distance between the waterway tunnel inspection device and the waterway tunnel in the vertical downward direction is provided.
The controller is a waterway tunnel inspection device that controls the thrust generated by the thrust generating mechanism in the vertical direction perpendicular to the horizontal plane based on the third sensor value. The waterway tunnel inspection apparatus according to any one of claims 1 to 7.
In addition
A frame with multiple frame bars, front and rear joints,
Equipped with a belt
One end of each of the plurality of frame bars is coupled to the front joint, and the other end is coupled to the rear joint.
The plurality of frame bars are arranged apart from each other around an axis connecting the front joint and the rear joint.
The balloon is housed in a space surrounded by the plurality of frame bars.
A waterway tunnel inspection device in which the belt is wrapped around the balloon and the frame. It is a control method of a waterway tunnel inspection device equipped with a balloon filled with a gas having a specific gravity lighter than that of air and configured to fly inside the waterway tunnel.
The first control that generates a thrust for turning the reference axis set in the waterway tunnel inspection device in the horizontal plane, and the thrust for moving the waterway tunnel inspection device in the horizontal plane in the direction perpendicular to the reference axis. Including the step of selectively performing the second control that occurs.
When the inclination angle of the reference axis with respect to the extension direction of the waterway tunnel is out of the specified range, the first control is preferentially performed without performing the second control.
A control method for a waterway tunnel inspection device that performs the second control when the inclination angle is within the specified range.

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