JP6830584B2 - Building inspection robot - Google Patents

Description

The present invention relates to a building inspection robot. In particular, it concerns inspection robots under the ceiling and under the floor.

The ceiling constitutes the upper surface of the indoor space, and pipes, wiring, ducts, etc. are arranged, and fire resistance, soundproofing, heat insulation, lighting and air conditioning equipment are also installed to fulfill the indoor environment maintenance function. The ceiling on which such various devices are arranged is a suspended ceiling type.
The suspended ceiling is generally configured by lowering a hanging bolt from a concrete slab to attach a field edge receiver, attaching a field edge to this field edge receiver, and attaching a ceiling material to the field edge. Gypsum board and lock rule board are used for the ceiling material, and although they are lightweight and fire resistant, their strength is low and workers cannot enter and work. In the past, inspections and investigations were completed within the range visible from the inspection port, but it has been pointed out that a wide range of investigations are necessary in the wake of the ceiling fall accident caused by the earthquake.
The risk of accidents due to falling ceilings is especially significant in large buildings, such as gymnasiums and halls that serve as evacuation facilities.
Since the inside of the ceiling is narrow, dark, and composed of non-structural members, it is difficult for people to enter, and the actual situation of the attic inspection work is that investigators mainly work near the 450 mm square ceiling inspection port. We look into the attic and inspect (photograph) the main suspended ceiling components within the range that can be visually grasped. This is because the situation near the inspection port can be recorded as a typical part, but the situation at a place relatively far from the inspection port cannot be grasped.
For this reason, in response to the ceiling collapse accident at the time of the great earthquake, the obligation to inspect the attic part has been strengthened by national legal measures, and the inspection inspection is not limited to the vicinity of the ceiling inspection entrance, but it is a relatively inspection opening that is often overlooked. It is required to carry out detailed inspections (shooting records) even in narrow areas inside the ceiling away from the ceiling.

Patent Document 1 discloses an underfloor inspection method using a crawler type traveling body, which detects the position of the traveling body provided by the traveling body by using a camera and an ultrasonic range finder.
In Patent Document 2, a movable auxiliary camera is installed near the ceiling inspection port, and a computer capable of wireless communication between the robot and the auxiliary camera is provided, and the computer receives data from the robot and the auxiliary camera. However, the posture sensor detects and controls the running, and the robot stops at a larger inclination, and the image taken by the camera and the image taken by the auxiliary camera are displayed on the monitor screen of the computer almost at the same time without the robot tipping over. A robot system has been proposed that can continue monitoring and can observe the inside of the ceiling and capture the robot.

JP-A-2009-8528 Japanese Unexamined Patent Publication No. 2011-136380

An object of the present invention is to develop a robot capable of inspecting the attic and underfloor by entering through an inspection port.

1. 1. A building inspection robot equipped with a camera on the front side
It is a building inspection robot equipped with a main crawler device installed on the left and right sides of the main body and sub-crawler devices installed on the front and back of the main body.
There is a space for accommodating the camera between the left and right main crawlers.
A camera is mounted in the accommodation space so that it can be raised and lowered .
It is large enough to enter through the inspection port on the ceiling of the building.
Lighter than the ceiling load capacity of system ceiling materials,
The camera is in a low position during basic driving,
The low position of the camera should be below the height of the main body, and the upper surface of the field edge receiver should be visible.
A building inspection robot featuring.
2. 2. The main crawler is rear-wheel drive,
The front rotation axis of the main crawler is supported by the left and right supports extending from the main body,
The accommodation space of the camera is characterized in that it is formed between the left and right supports. The listed building inspection robot.
3. 3. The low position of the camera is the height that does not exceed the height of the main body,
The shooting position of the camera is characterized in that it is in the range of the height to which the elevating length of the elevating device of the camera and the standing length of the sub crawler are added. Or 2. The listed building inspection robot.
4. The camera elevating device includes a rotating frame and a support attached to the tip of the frame, and the support has a mechanism for maintaining horizontality with respect to the rotation of the frame. .. ~ 3. The building inspection robot described in any of.
5. Building inspection robot is provided with a driving performance to overcome the obstacles raised position equivalent to the height of the camera lifting apparatus, it is characterized by 1. ~ 4. The building inspection robot described in any of.
6. The camera has a pan / tilt (up / down / left / right control) function, which is used for both robot operation and inspection. It is equipped with a display, an operation device and a recording device, and the robot's running and camera operation are independent of each other. It is characterized in that it can be performed by radio control. ~ 5. The building inspection robot described in any of.
7. It is characterized by being used for attic inspection. ~ 6. The building inspection robot described in any of.
8.1. ~ 7. Use the building inspection robot described in any of the above to drive in a narrow building space, check the condition of the subject, adjust the shooting height of the camera, and acquire an image of the inspection location. A building inspection method characterized by this.

1. 1. We were able to develop a robot that can inspect the attic and underfloor by entering through the inspection port. We have realized a building inspection robot that is lightweight, compact, and has a camera function that can shoot at a high position that can run behind the ceiling.
2. 2. You can go into the narrow ceiling or under the floor, drive over obstacles, and raise and lower the camera to take pictures, so you can investigate and inspect a wide area.
3. 3. Due to the structure of the ceiling, the height of the robot needs to be suppressed to about 1 mm, while the height of the robot, such as a field edge receiver, needs to be about 150 mm. Since the sub-crawler climbs over obstacles and leans forward to touch the ground, it is possible to prevent the occurrence of an impact that collides with the ceiling material and to run without damaging the ceiling material.
At least, with the elevating device raised, the height is set so that it can be confirmed by overcoming an obstacle whose upper surface can be confirmed, and this is about 150 mm.
The field edge receiver, which is the basic configuration of the suspended ceiling, has a height of about 65 mm, and the low position of the camera is set to a height at which the surrounding conditions can be confirmed by looking at the field edge receiver.
In addition, when the sub-crawler is erected, a higher camera position can be obtained, so it is possible to avoid obstacles in front of the user and investigate and inspect hidden areas.

It is a figure which shows the outline of a building inspection robot. It is a figure which shows the example of the height adjustment of a camera. It is a figure which shows the main structure of an inspection robot. It is a figure which shows the outline of the inspection method. It is a figure which shows the example of the inspection run of the ceiling. It is a figure which shows an example of the inspection flow. An example of the control system diagram of the inspection robot is shown. It is a figure which shows the shooting state by the difference of the height low, middle and height of a camera. It is a figure which shows the structural example of the elevating support part tool of a camera. It is a figure which shows the example of the suspended ceiling.

The present invention is a robot that inspects a building such as an attic.
The building inspection robot of the present invention includes a traveling machine equipped with a traveling mechanism by a crawler method and a photographing mechanism equipped with a camera.
Compact and lightweight, it has the ability to shoot safely even at high positions, and has the ability to drive safely over low body heights and field rims, which can be used for ceiling-mounted equipment and ceiling material mounting structures. Inspection robot.
Inspection points include the attic, underfloor, piping space, machine room, and other areas that cannot be easily approached by investigators.
The inspection is visual inspection by a camera and recording of images, and includes joints, water leak marks, rust, construction status, construction records, and the like.

[Outline of robot structure]
The present invention is a crawler-type traveling robot equipped with a camera, and includes main crawlers provided on the left and right sides of the main body and arm-shaped sub-crawlers provided at four corners.
A camera is attached to the elevating support on the main body.
The sub crawler is driven separately from the main crawler and has a structure in which the entire sub crawler rotates like an arm.
The crawler-type traveling robot of the present invention has a size that allows it to pass through an inspection port such as a ceiling, is lightweight on the ceiling, has a low body height corresponding to a low space such as the ceiling, and has a field edge or a field edge receiver. It has running performance to overcome steps.
The camera is attached to a support that expands and contracts in the height direction attached to the main body. By adjusting the shooting height of the camera, it is possible to avoid obstacles and shoot, or to improve the observation accuracy of the subject. The camera is equipped with a pan / tilt function and can adjust the horizontal direction and vertical angle, so in addition to adjusting the height, it is possible to observe and shoot almost the entire circumference of the traveling robot.
As the telescopic mechanism, an X-link elevating mechanism, a folding link used for aerial work platforms, a rack-pinion, or the like can be used.
In addition to the camera, it is equipped with LEDs for lighting, and if necessary, sensors such as a thermometer, gas sensor, and hygrometer will be installed.
This camera-equipped crawler-type traveling robot is radio-controlled so that the camera can be controlled separately from traveling.
This robot is suitable for inspecting the ceiling of a building. For example, in a suspended ceiling space composed of a ceiling board and various hanging metal fittings, this robot overcomes the steps of the field edge of the ceiling base material and the field edge receiver, and also slips through the gaps of ducts and wirings. However, using a small inspection traveling robot that can travel on the ceiling board by wireless remote control from the ground, the inside of the ceiling is out of sight by a conventional investigator (person). Shoot and record every detail.
The inspection location of the building is the attic, underfloor, piping space, machine room, and other areas that cannot be easily approached by investigators. The inspection is visual inspection with a camera and recording of images, such as joints, water leak marks, rust, construction status, and construction status.

An example of a crawler-type traveling robot A equipped with a camera (hereinafter, may be simply referred to as an “inspection robot”) will be described with reference to the drawings.
FIG. 1 shows an overall outline of the inspection robot.
It is equipped with main crawlers 3 and 3 provided on the left and right sides of the main body 2 and four sub crawlers 4, 4, 4 and 4 provided on the front and back of the main body 2, and the camera 5 can be expanded and contracted in the height direction. It is a crawler type traveling robot A attached to a support member and operated wirelessly.
The camera has a storage space provided between the left and right main crawlers on the front side of the machine body 1, and an elevating support 6 is provided in the storage space.
An LED is provided on the upper surface of the main body for lighting. It is set to be scattered light so that the surroundings of the robot body are bright.
This inspection robot is basically facing the camera side.
The main crawler 3 is driven by the rear wheels, and the sub crawler 4 is driven coaxially on the left and right sides of the front side and the rear side, respectively.
The sub crawler 4 is driven separately from the main crawler, and is a mechanism that allows the crawler to swing like an arm. The sub crawler not only improves the step running performance, but also has the function of increasing the shooting height of the camera.
This inspection robot is radio-controlled, and the camera is equipped with a mechanism that is controlled separately from the traveling device during inspection.

FIG. 2 shows an example of adjusting the height of the camera.
FIG. 2A shows the basic posture in which the camera 5 is in the low position. The upper end of the camera 5 is approximately the height L1 of the body height of the main body 2. This height is the minimum as a traveling space, and the traveling posture is stable.
The height L1 can be set by paying attention to avoiding the basic elements of the building to be inspected, for example. If it is a ceiling, pay attention to the field edge and the field edge receiver, and since the field edge receiver is at a height of 65 mm, set the camera position to a height that allows you to see beyond that. This makes it possible to determine the height of the aircraft.
FIG. 2B shows the camera at a height L2 at the middle position with the elevating device 6 raised.
The inspection point can be observed beyond the obstacle in front, and the viewpoint of the inspection point can be changed by changing the height, and more accurate image information can be obtained.
This inspection robot can run over obstacles, and if the sub-crawler is swung up and touches the upper corner, it is possible to climb as long as the center of gravity is not behind, but the situation after climbing. If is unknown, it cannot be operated. If the robot cannot run on its own, it will be difficult to collect the robot.
The height L2 at the middle position is a practical operation for safely overcoming an obstacle at a height at which the upper surface can be seen through the camera. Therefore, at least, the height L2 at the middle position is significant even if it is the minimum height at which the vehicle can safely run on a step.
For example, in the case of a ceiling, a lighting box can be exemplified.
FIG. 2C shows a state in which the camera is set to a height L3 at a high position.
The four sub-crawlers 4 are erected to lift the aircraft. The height is gained by adding the amount that the aircraft has risen to the middle position. As a result, it is possible to observe in detail by changing the distance and the angle from the middle position.
FIG. 8 illustrates a shooting state due to the difference in height of the camera. Observing from each height, you can clearly see the state of the field edge, the state of the field edge support, and the joint state. In addition, even if there is a low obstacle in the foreground, it can be observed from above, and the depth can be seen well in the distance.

FIG. 3 shows the main structure of the inspection robot.
A parallel support member 23 is attached to the front and rear corners of the main body 2, and a pulley 32 for the main crawler is installed.
The rear pulley 32b for the main crawler is a drive pulley to which the drive motor 24 is attached. Separate drive motors are installed on the left and right rear pulleys 32b, and they are driven and controlled individually.

The sub crawler 4 attaches the sub original pulley 42 to the outside of the support member 23. The sub original pulley and the sub tip pulley 43 are attached via the sub frame 41.
The left and right sub-crawlers provided on the front side are connected by a sub-crawler 45a, and the sub-crawler 45a is driven by a drive motor 44a for the front sub-crawler. The left and right sub crawlers provided on the rear side are also connected by the sub shaft 45b and driven by the rear sub crawler drive motor 44b.
The drive motors 44a and 44b for the front and rear subcrawlers move the subframe 41. The sub-source pulley is a driven drive that rotates coaxially with the pulley 32.
In particular, the front sub-shaft 45a is arranged below the support member 23, and the drive motor 44a is arranged closer to the main body side than the support member to form a space between the left and right support members 23. There is. On the other hand, on the rear side, two drive motors 24 and 24 for the main crawler and a rear sub crawler drive motor 44b are arranged between the left and right support members 23, and a gap is provided. Not.

FIG. 9 shows a configuration example of the elevating support member of the camera. (A) shows the raised state, and (b) shows the low position state.
An elevating device is attached so that the camera 5 is housed in the space formed between the left and right support members 23 on the front side.
The frame 61 is provided on the main body side of the support plate 23. A base 62 for mounting a camera is provided on the tip end side of the frame. A servomotor 63 for controlling frame rotation is attached to the base end portion of the frame 61.
The frame 61 is composed of two parallel frames, and the servomotor 63 is provided on the proximal end side of one of the frames 61a. A timing belt 64 is attached to the other frame 61b, and the timing belt moves together in response to the rotation of the frame to keep the base 62 horizontal. At the base end of the frame 61b, a sun gear and a planetary gear are combined to rotate the timing belt in the direction opposite to the rotation of the sun gear coaxial with the frame 61b to maintain the level of the table.
In the low position, the frame 61 is accommodated between the left and right support members 23, and the camera 5 mounted on the base 62 can also maintain a sufficiently low posture.

FIG. 7 shows an example of a control system diagram of the inspection robot.
On the traveling robot body side, a control PC for maneuvering control and a survey camera (also used for traveling) are provided as separate systems.
A microcomputer board for LEDs and motor drivers for four DC motors (2 for the main crawler and 2 for the sub crawler) are connected to the control PC. The camera goes up and down via the microcomputer board.
On the control side, a controller for running operation and an operation PC for running are provided. The camera is operated by a tablet PC separately from the operation PC. Travel maneuvering can be performed while looking at the screen of the tablet PC.

The camera has a pan / tilt function, and the height, direction, and vertical angle can be adjusted. It is used for both running robots and inspection and observation. It is possible to observe and photograph almost the entire circumference of the inspection robot. It is set so that it can be controlled independently for inspection and observation.
The inspection robot is radio-controlled, and inspection photography is controlled separately from the operating PC.
The position of the inspection robot can be confirmed by providing a signal transmission function and displaying it on a display provided on the controller side. Since this inspection robot is driven by a motor, it is possible to confirm the position without providing a device for transmitting a special signal.
The records of inspection points (photographed points) can be matched by importing the photographed points into a PC if the architectural drawings are converted into electronic data. If it is a paper drawing, keep an inspection record by writing it on the drawing.

This inspection robot is a size that can be entered from the inspection port of the building, and has weight and exercise performance that does not damage the strength of the ceiling.
For example, the inspection port is configured as follows, taking a ceiling that is 45 cm square as an example.
-Overall length: 350 mm Width: 250 mm Height: 90 mm
・ Weight: 4.5kg
・ Drive system: Crawler type (6 crawler type)
・ Motor: DC motor
・ Step overcoming performance: 150 mm or more
・ Maximum moving speed: 1.2m / s
・ Power: Lithium-ion battery (replaceable)
・ Continuous operation time: about 2 hours
・ Communication method: Wireless LAN
・ Camera height: 90mm, 200mm, 300mm

[Outline of inspection method]
FIG. 4 shows an outline of the inspection method.
The inspection robot of the present invention is used as a method for inspecting buildings such as under the ceiling and under the floor. The inspection method will be described below by taking the attic inspection method as an example.
As the inspection robot used in this example, a total length of 350 mm, a width of 250 mm, a height of 90 mm, and a weight of 4.5 kg, which can be entered from the above-mentioned 45 cm square inspection port, were used.
This inspection robot overcomes the step of the ceiling base material and the step of the field edge receiver in the suspended ceiling space mainly composed of the ceiling board and various hanging metal fittings, and also goes through the gaps of ducts and wirings. It is a small inspection robot that can run on the attic board by wireless remote operation from the ground while pulling out, and it shoots and records details inside the attic that the conventional investigator (person) cannot see.
The investigator (remote operator) wirelessly remotely controls the real-time video data inside the attic sent from the camera mounted on the inspection robot while looking at the dedicated computer monitor screen, and inside the attic required as survey record data. Use the camera to record the situation.

An inspection robot that can run behind the ceiling by wireless remote control is inserted through the inspection port and installed behind the ceiling. Drive while ensuring visibility with the on-board camera, overcome low obstacles such as field edges and field edges, and approach the inspection point. If there is an obstacle that obstructs the eyes of the mounted camera when approaching the inspection target and it is necessary to shoot and record the area ahead, move the camera body up and down to change the camera height position and shoot and record.
The camera mounted on the inspection robot has a pan / tilt (swing) function, and the direction and angle of the camera lens can be remotely controlled up, down, left, and right while the robot is stopped without running. It can be changed to investigate and record in almost all directions. The inspection robot used in this example can photograph a range of 2 to 3 m as shown in FIG.

FIG. 5 shows an example of an inspection run behind the ceiling.
An investigator places the inspection robot A on the ceiling board from the ceiling inspection port using scaffolding, etc., and then the robot is placed in place while viewing the video data from the mounted camera by remote control wirelessly on the computer monitor screen. Run to move. The inspection robot travels remotely while overcoming the field edge and field edge support of the ceiling base material and sneaking through the gaps, and the on-board camera captures the image data inside the ceiling into a personal computer and saves and records it. The inspection robot records photographs taken in each area behind the ceiling and returns to the inspection port for repair.
Since there are multiple ceiling inspection ports, access from another inspection port to inspect places where it is difficult to get over, such as ducts and air conditioners attached to the ceiling.

FIG. 6 shows an example of the inspection flow.
An inspection robot that can run behind the ceiling by remote control by wireless is inserted from the inspection port and installed behind the ceiling, and the inspection robot is equipped with a camera, and the camera remotely controls the robot. The camera control mounted on the inspection robot can be remotely controlled by the investigator (remote operator) wirelessly, and the investigator inspects while looking at the video monitor screen transmitted from the camera of the personal computer (tablet type terminal) dedicated to the camera. Operate the inspection robot device behind the ceiling by operating the controller connected to the personal computer dedicated to the robot.
The inspection robot installed behind the ceiling lowers the camera, operates the forward lever of the controller, and travels while overcoming steps such as field edges by radio control.
If there is a low obstacle that obstructs the running, operate the lever to stop the running. With the stopped body, the camera support is raised to set the camera in the middle position.
Operate the camera in the middle position from a camera operation PC such as a tablet terminal to check the top surface of the obstacle and beyond. If it is possible to shoot, shoot and record over a low obstacle in front of the inspection robot.
After shooting, confirm that you can safely get over it, keep the camera as it is or lower it, operate the controller, and proceed over the low obstacles. If it is difficult to get over, go around and if you face a high obstacle, raise the camera support and the aircraft, raise the camera to a high position, and check the surroundings. If it is possible to take a picture, operate the camera operating PC to take a picture and record it.
After the shooting is completed, the inspection robot is run in a low position.
The order of the heights of obstacles located in front of the inspection robot is set for the sake of explanation, and in reality, the height of the camera is adjusted according to the state of the obstacles encountered.
The real-time image from the camera is projected on the camera-dedicated personal computer (tablet terminal), and the investigator operates the controller while watching the monitor image, and if necessary, the camera-dedicated personal computer (tablet terminal) is used inside the ceiling. Record and save the shooting data of.

A Crawler type traveling robot (inspection robot)
1 Main body 23 Support member 24 Drive motor 3 Main crawler 32 Pulley 32a Front pulley 32b Rear pulley 4 Sub crawler 41 Sub frame 42 Sub original pulley 43 Sub front pulley 44a Front sub crawler drive motor 44b Rear sub crawler drive motor 45a , 45b Sub-axis 5 Camera 6 Elevating support 61 Frame 62 units 63 Servo motor 64 Timing belt 9 Scanning device 91 Traveling device PC
92 Controller for traveling device 93 PC for camera
100 Ceiling 110 Inspection port

Claims (8)

A building inspection robot equipped with a camera on the front side
It is a building inspection robot equipped with a main crawler device installed on the left and right sides of the main body and sub-crawler devices installed on the front and back of the main body.
There is a space for accommodating the camera between the left and right main crawlers .
A camera is mounted in the accommodation space so that it can be raised and lowered.
It is large enough to enter through the inspection port on the ceiling of the building.
Lighter than the ceiling load capacity of system ceiling materials,
The camera is in a low position during basic driving,
The low position of the camera should be below the height of the main body, and the upper surface of the field edge receiver should be visible.
A building inspection robot featuring. The main crawler is rear-wheel drive,
The front rotation axis of the main crawler is supported by the left and right supports extending from the main body,
The building inspection robot according to claim 1, wherein the accommodating space of the camera is formed between the left and right supports. The low position of the camera is the height that does not exceed the height of the main body,
The building inspection robot according to claim 1 or 2, wherein the shooting position of the camera is in a height range in which the elevating length of the elevating device of the camera and the standing length of the sub-crawler are added. The elevating device of the camera includes a rotating frame and a support attached to the tip of the frame, and the support is provided with a mechanism for maintaining horizontality with respect to the rotation of the frame. The building inspection robot according to any one of Items 1 to 3. Building inspection robot,
And a driving performance to overcome the obstacles raised position equivalent to the height of the camera lifting apparatus,
The building inspection robot according to any one of claims 1 to 4. The camera has a pan / tilt (up / down / left / right control) function, which is used for both robot operation and inspection. It is equipped with a display, an operation device and a recording device, and the robot's running and camera operation are independent of each other. The building inspection robot according to any one of claims 1 to 5, wherein the robot can be operated by radio control. Building inspection robot according to claim 1, characterized in that is used for ceiling inspections. The building inspection robot according to any one of claims 1 to 7 is used to drive in a narrow space of a building, check the condition of the subject, adjust the shooting height of the camera, and perform the inspection location. A building inspection method characterized by acquiring an image of.

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