JP2020169921A - Surveying robot and surveying robot system - Google Patents

Abstract

To provide an inexpensive and compact surveying robot and a surveying robot system for measuring a ground surface elevation profile.SOLUTION: A surveying robot 20 comprises: a light receiving sensor unit 34 including a light receiving sensor 21 for receiving a gyrating laser beam L that is emitted from a rotary laser device 10 and serves as a height reference and a distance measurement part 22 for measuring the height of the light receiving sensor; a moving vehicle 31 having the light receiving sensor unit 34 mounted therein and self-traveling a preset path; an inclination sensor 23 for detecting the inclination of the moving vehicle 31; a position acquisition part 24 for acquiring the position of the moving vehicle; and a control processing part 26 for calculating a ground surface elevation profile on the basis of the detection results of the light receiving sensor 21, distance measuring part 22, inclination sensor 23 and position acquisition part 24. The light receiving sensor 21 is constituted so as to be capable of receiving light from 360° directions around the height direction axis and moving in the height direction, always receiving the gyrating laser beam L at a middle position M in the height direction.SELECTED DRAWING: Figure 4

Description

The present invention relates to a surveying robot and a surveying robot system that measure a ground height profile using a swirling laser beam.

Conventionally, light-receiving position information obtained by receiving a swirling laser beam emitted by a rotating laser device installed at a reference point on the ground with a height difference by a light-receiving sensor mounted on a moving body that autonomously travels on the ground. Therefore, a surveying robot that performs level surveying of the ground is known (Patent Document 1 and the like).

The surveying robot of Patent Document 1 arranges three optical sensors in an N shape, and measures the ground height profile from the received light reception time information and the position information obtained by the optical sensors receiving the swirling laser beam. ..

Japanese Unexamined Patent Publication No. 9-021635

However, in the surveying robot of Patent Document 1, since the light receiving sensor is arranged in an N shape, there is a problem that the size of the entire surveying robot becomes large and the cost increases in order to secure the height. In addition, it is necessary to use at least three long light receiving sensors, which also causes a problem that the cost increases.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide an inexpensive and compact surveying robot and surveying robot system for measuring a ground height profile.

In order to achieve the above object, the surveying robot according to one aspect of the present invention receives a swirling laser beam as a height reference emitted from a rotating laser device, and detects a light receiving position, and a light receiving sensor described above. A light receiving sensor unit that includes a distance measuring unit that measures the height of the light receiving sensor, a moving body that is equipped with the light receiving sensor unit and autonomously travels on a preset path, and a tilt sensor that detects the tilt of the moving body. And the position acquisition unit that acquires the position of the moving body,
It includes a light receiving sensor, a distance measuring unit, an inclination sensor, and a control processing unit that calculates a ground height profile based on the detection results of the position acquisition unit.
The light receiving sensor is configured to be able to receive light from the 360 ° direction around the axis in the height direction and is movable in the height direction, and constantly receives the swirling laser light at the central position in the height direction.

In the above aspect, it is also preferable that the light receiving sensor is configured to be able to receive light from the 360 ° direction around the axis by providing the light receiving portion on the entire circumference around the axis in the height direction of the light receiving sensor.

Further, in the above aspect, it is also preferable that the light receiving sensor is configured to be rotatable around the axis of the light receiving sensor so that it can receive light from the 360 ° direction around the axis.

Further, it is also preferable that the control processing unit further includes a notification unit that notifies an abnormality when the light receiving sensor unit cannot receive the swirling laser light at the center in the height direction.

Further, the measuring robot system according to another aspect of the present invention includes a rotating laser device that emits a swirling laser beam as a height reference, a light receiving sensor that receives the swirling laser beam and detects a light receiving position, and the above. A light receiving sensor unit including a distance measuring unit that measures the height of the light receiving sensor, a moving body that is equipped with the light receiving sensor unit and autonomously travels on a preset path, and a tilt sensor that detects the tilt of the moving body. A position acquisition unit that acquires the position of the moving body, and a control processing unit that calculates the ground height profile based on the detection results of the light receiving sensor, the distance measurement unit, the inclination sensor, and the position acquisition unit. The light receiving sensor is configured to be capable of receiving light from a 360 ° direction around an axis in the height direction and movable in the height direction, and constantly receives the swirling laser beam at a central position in the height direction.

According to the above configuration, it is possible to provide an inexpensive and compact surveying robot and surveying robot system for measuring the ground height profile.

It is a block diagram of the structure of the surveying robot system which concerns on 1st Embodiment of this invention. It is a schematic diagram of the appearance of the surveying robot system. It is a schematic appearance figure of the light receiving sensor of the surveying robot system. It is a figure explaining the measurement operation of the surveying robot system. It is a block diagram of one modification of the surveying robot system. It is a block diagram of the structure of the surveying robot system which concerns on 2nd Embodiment of this invention. It is a schematic diagram of the appearance of the surveying robot system. It is a schematic appearance figure of the light receiving sensor of the surveying robot system. It is a figure explaining the rotational drive of the light receiving sensor of the surveying robot system.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings, but the present invention is not limited thereto. Further, in each embodiment, the same configurations are designated by the same reference numerals, the same types of configurations are designated by the same names, and duplicate description will be omitted as appropriate.

(First Embodiment)
FIG. 1 is a block diagram of the configuration of the surveying robot system 1 according to the first embodiment, and FIG. 2 is a schematic view of the appearance. The surveying robot system 1 is a system that measures the height profile of the ground having a height difference.

The surveying robot system 1 includes a rotating laser device 10 and a surveying robot device 20.

The rotary laser device 10 is erected at a measurement reference point on the ground via a leveling table, and emits a swirl laser beam L that rotates or scans in a horizontal plane at a predetermined swivel angle.

As shown in FIG. 1, the surveying robot device 20 includes a light receiving sensor 21, a distance measuring unit 22, an inclination sensor 23, a position acquisition unit 24, a sensor unit elevating drive unit 25, a control processing unit 26, and a storage unit 27. And. The control processing unit 26 is connected to each element.

Further, as shown in FIG. 2, at least the light receiving sensor 21, the distance measuring unit 22, the tilt sensor 23, the position acquisition unit 24, and the sensor unit elevating drive unit 25 are mounted on the moving body 31. The moving body 31 is, for example, a vehicle or a trolley, and is configured to autonomously travel on the ground on a preset route by a known method.

As shown in FIG. 3, the light receiving sensor 21 has a cylindrical shape. Further, the light receiving unit 29 includes a photodiode that receives the swirling laser beam L and outputs a light receiving signal. A mounting hole 21a for mounting on the shaft portion 35 is provided in the center of the light receiving sensor 21. The light receiving unit 29 is provided on the entire circumference around the axis V in the height direction of the light receiving sensor 21 so that the swirling laser beam L can be received from the 360 ° direction around the axis V. Further, the light receiving unit 29 is configured so that the light receiving position of the swirling laser beam L can be detected.

Further, the light receiving sensor 21 is provided with an indicator 32 indicating the incident position of the swirling laser beam L on the light receiving portion 29. As for the indicator 32, for example, LED lights 32a, 32b, 31c of three colors of yellow, green, and red are arranged over the entire circumference in the circumferential direction, and the lighting color and the lighting color are changed according to the incident position of the swirling laser light. By changing the blinking pattern, the user can determine whether the height of the swirling laser light L incident on the light receiving portion 29, particularly whether the swirling laser light L is incident on the central position M in the height direction of the light receiving sensor 21. Can be recognized. ..

The distance measuring unit 22 is a small electronic range finder, which includes a running light unit and a light receiving unit, emits distance measuring light pulsed from the running light unit toward a pedestal 33 described later, and reflects light from the pedestal 33. the then received by the light receiving unit, based on the time and speed of light until receiving the laser beam, by measuring the distance l ₁ to the pedestal 33 from the distance measuring unit 22, the height from the ground of the light receiving sensor 21 Measure.

The light receiving sensor 21 and the distance measuring unit 22 are integrally configured as a light receiving sensor unit 34. The light receiving sensor unit 34 is provided coaxially with the shaft portion 35 by inserting the shaft portion 35 erected orthogonally to the pedestal 33 installed on the moving body 31 into the mounting hole 21a. As a result, the optical axis of the distance measuring light of the distance measuring unit 22 is parallel to the shaft unit 35. Further, the sensor unit elevating drive unit 25, which will be described later, is configured to be movable up and down in the height direction along the shaft unit 35. The shaft portion 35 is preferably provided at the center of the moving body 31.

The tilt sensor 23 is a tilt sensor that detects the tilt of the moving body 31 in the XY2 axis directions.

The position acquisition unit 24 acquires the position information of the moving body 31. As the position acquisition unit 24, for example, a GNSS device that receives a navigation signal from a navigation satellite and acquires its own position can be used. Alternatively, the position information of the moving body 31 may be acquired by combining the wheel encoder attached to the wheel of the moving body 31 and the acceleration sensor. When the position acquisition unit 24 is a GNSS device, it can be used for outdoor measurement. The combination of wheel encoder and accelerometer is suitable for indoor measurement.

As the sensor unit elevating drive unit 25, for example, a ball screw is used as a shaft portion 34, a ball screw nut is provided on the inner peripheral surface of the mounting hole 21a of the light receiving sensor unit 34, and a rotary motion of a rotary motor connected to the ball screw is performed. A ball screw linear motion mechanism that transmits the ball screw and causes the ball screw to move linearly up and down via the bearing inside the ball screw nut can be used.

Further, as the sensor unit elevating drive unit 25, for example, a shaft provided with a permanent magnet is used as a shaft portion 34, a coil is provided in the vicinity of the mounting hole 21a of the light receiving sensor unit 34, and the shaft motor is directly moved up and down by electromagnetic force. A dynamic mechanism may be used. When using the ball screw linear motion mechanism, it is necessary to provide a linear guide (not shown), and the linear guide may cover a part of the light receiving portion 29, but the width thereof is the width of the light receiving sensor 21. It is configured so as not to interfere with light reception from the 360 ° direction.

The control processing unit 26 performs various controls and processes for exerting the functions of the measuring robot 20. The control processing unit 26 controls the sensor unit elevating drive unit 25 in response to the detection of the light receiving position of the swirling laser beam L by the light receiving sensor 21, and the center position M in the vertical direction of the light receiving sensor 21 is always swirling laser. It is set to the light receiving position of the light L.

The control processing unit 26 synchronously controls the measurement of the light receiving sensor 21, the distance measuring unit 22, the tilt sensor 23, and the position acquisition unit 24. The control processing unit 26 calculates the ground height profile based on the measurement results of the light receiving sensor 21, the distance measuring unit 22, the inclination sensor 23, and the position acquisition unit 24.

The control processing unit 26 may include any electric circuit (or a portion thereof). The circuit may be in any form, including, for example, an integrated circuit, a collection of integrated circuits, a microcontroller, a microprocessor, a collection of individual electrical components on a printed circuit board (PCB), and the like. The control processing unit 26 may be incorporated in the surveying robot 20, stand-alone, or be a part of a separate personal computer. In the example of FIG. 2, the control processing unit 26 is mounted on the moving body 31 as a personal computer 36 together with the storage unit 27 and the operation unit 28.

Further, the function of the control processing unit 26 may be realized by a circuit or may be realized by executing a program. When realized by a program, the program may be stored in a storage medium such as a magnetic disk, a flexible disk, an optical disk, a compact disk, a Blu-ray (registered trademark) disk, or a DVD.

The storage unit 27 stores each measurement data and the ground height profile calculated by the control processing unit 26. The storage unit 27 includes a RAM (Random / Access / Memory) as a main storage device, a ROM (Read / Only / Memory), an HDD (Hard / Disc / Drive) as an auxiliary storage device, and the like.

The operation unit 28 is a device for the user to input an instruction to the surveying robot 20, and includes, for example, a mouse, a touch pad, a keyboard, an operation panel, a joystick, a button, and a switch.

<Measurement of ground height profile>
FIG. 4 is a diagram showing the operation of the surveying robot 20 when the surveying robot system 1 is used to measure the ground having a height difference. The surveying robot 20 is set at the measurement start position (A) so that the swirling laser beam L matches the central position M of the light receiving unit 29.

For the setting of the center position M, for example, the user adjusts the height of the rotary laser device 10 to adjust the swirling laser light L to the central city, and the indicator 32 confirms that the swirling laser light matches the center position M. After that, it may be performed by inputting the completion of the setting to the surveying robot 20.

The moving body 31 is set in advance so as to autonomously travel in a predetermined measurement area. When the measurement is started, the light receiving sensor 21, the distance measuring unit 22, the tilt sensor 23, and the position acquisition unit 24 perform their respective measurements at predetermined intervals under the synchronous control of the control processing unit 26, and the control processing unit 26 detects. Output data.

When the surveying robot 20 moves in a direction in which the ground height becomes lower as in (B), the swirling laser beam L is incident on a portion above the central position M of the light receiving portion 29. When the control processing unit 26 detects that the light receiving position is higher than the center position M, the control processing unit 26 controls the sensor unit elevating drive unit 25 to move the sensor unit upward, and the light receiving position is moved to the center position M. Make sure it matches.

On the other hand, when the surveying robot 20 moves in the direction of increasing the ground height as in (C), the swirling laser beam L is incident on a portion below the central position M of the light receiving portion 29. When the control processing unit 26 detects that the light receiving position is lower than the center position M, the control processing unit 26 controls the sensor unit elevating drive unit 25 to move the light receiving sensor unit 34 downward, and the light receiving position is at the center position. Make it match M. In this way, in the light receiving sensor 21, the center position M in the vertical direction of the light receiving unit 29 is set to the light receiving position of the constantly swirling laser beam L.

Then, as shown in (D), when the light receiving sensor unit 29 reaches the movement limit 39a at the upper end of the shaft unit 34, the control calculation unit 26 stops driving the sensor unit elevating drive unit 25. When the movement of the light receiving sensor unit 29 is stopped and the surveying robot 20 moves in a direction in which the ground height is further lowered, the swirling laser beam L is incident above the central position M. However, the light receiving sensor unit 29 does not move further upward. Therefore, the swirling laser beam L cannot be returned to the central position M. In this case, the control processing unit 26 stops all measurements. The same applies when the light receiving sensor unit 29 reaches the movement limit 39b at the lower end of the shaft portion 34.

In this case, the user can continue the measurement by adjusting the height of the rotary laser device 10 again and adjusting the swirling laser beam L to the center position M.

<Calculation of ground height profile>
Next, the calculation of the ground height profile will be described with reference to FIG. First, the height H of the height reference plane created by the swirling laser beam L, the distance l ₂ between the vertical center position M of the light receiving sensor 21 and the measurement reference position of the distance measuring unit 22, and the height 1 _{3 of the} moving body 31. Is known.

The height h from the ground to the light receiving position M of the light receiving sensor 21 is obtained by the sum of the distance l ₁ obtained by the measurement and the distances l ₂ , l ₃ when the surveying robot 20 is on the horizontal plane. However, if the surveying robot 20 is tilted as shown in FIGS. 4 (B) and 4 (C), an error due to the tilt occurs. Therefore, the tilt angle θ obtained by the tilt sensor 23 is used and corrected by a trigonometric function to obtain the height h of the light receiving sensor 21 to the light receiving position.

Installation of the rotary laser device 10 by subtracting the height h of the light receiving position from the height H of the height reference plane created by the swirling laser beam L when the light receiving position is the center position M of the light receiving sensor 21. The height difference d between the surface and the traveling surface of the surveying robot 20 is calculated.

The ground height profile can be obtained by acquiring the height difference d obtained in this way for each position information at the synchronized time.

<Modification example>
As one modification of the present embodiment, as shown in FIG. 5, the surveying robot system 1a may include a notification unit 45 in the surveying robot device 20a.

Under the control of the control processing unit 26, the notification unit 45 cannot return the swirling laser beam L to the center position M when the light receiving sensor unit 34 reaches the movement limits 39a and 39b shown in FIG. 4D. When the swirling laser beam cannot be received at the center position in the height direction, the user is notified of the abnormality.

The notification unit 45 may be configured to notify by using the indicator 32 of the light receiving sensor 21 and rotating and blinking in red.

Alternatively, the notification unit 45 may be provided with a speaker and may emit a signal sound or the like. Alternatively, the notification unit 45 may be provided with wireless communication means and configured to transmit a warning message to a remote user's terminal.

In this way, even if the surveying robot 20 is remote, it can be seen that the swirling laser beam L deviates from the light receiving range of the light receiving sensor 21, so it is necessary to constantly monitor the measurement state of the surveying robot 20. The work load is reduced.

In the surveying robot system according to Patent Document 1, three light receiving sensors are arranged in an N shape, and the length of the light receiving sensors in the height direction defines a measurable height range. Therefore, if the measurable height range is to be increased, the lateral dimension is inevitably also increased.

In the surveying robot system 1 using the surveying robot 20 according to the present embodiment, the light receiving sensor 21 is configured to be movable in the height direction and constantly receives the swirling laser beam L, so that the stability of the surveying robot itself It is not necessary to increase the lateral dimension as long as it can be secured.

Further, since the light receiving sensor 21 constantly receives the swirling laser beam L while moving in the height direction, the required light receiving unit 29 can be reduced as compared with the surveying robot having the same measurable height range. it can.

Such an action contributes to a reduction in manufacturing cost, and therefore, according to the above configuration, it is possible to provide a surveying robot and a surveying robot system for measuring a ground height profile, which is inexpensive and compact.

Further, since the swirling laser light L is configured to be able to receive light from the 360 ° direction around the axis V, the swirling laser light L is not shielded by another member, and the swirling laser L can be reliably detected. It is also advantageous in terms of points.

Normally, in the measurement of the ground height profile, when the swirling laser beam deviates from the measurable range, it is necessary to manually adjust the height of the rotating laser device. According to the surveying robot device 20 and the surveying robot system 1 according to the present embodiment, the measurable height range is increased and the height of the rotating laser device is increased as compared with the surveying robot device using the light receiving sensor of the same size. The number of adjustments can be reduced.

<Second Embodiment>
FIG. 6 is a block diagram of the configuration of the surveying robot system 101 according to the second embodiment, and FIG. 7 is a schematic view of the appearance.

The surveying robot system 101 has the same configuration as the schematic surveying robot system 1, but differs in the following points.

As shown in FIG. 8, the light receiving sensor 121 has a semi-cylindrical shape, and an indicator 132 having the same configuration as the indicator 32 and a light receiving sensor 129 having the same configuration as the light receiving sensor 29 are provided along the circumferential surface. There is.

The light receiving sensor unit 134 is attached to the shaft portion 35 coaxially with the shaft portion 35 via the mounting structure 142 on the back surface of the light receiving sensor 121. Specifically, the mounting structure 142 is provided with a mounting hole (not shown), and the shaft portion 35 is inserted into the mounting hole to allow the sensor unit elevating drive unit 125 similar to the sensor unit elevating drive unit 25. As a result, it can be moved in the vertical direction along the shaft portion 35.

The mounting structure 142 includes a ball screw nut inside the mounting hole when the sensor unit elevating drive unit 125 is a ball screw linear motion mechanism, and when the sensor unit elevating drive unit 125 is a shaft motor linear motion mechanism. , The mounting structure is equipped with a coil.

Further, the light receiving sensor unit 134 is rotatably configured by a sensor unit rotation drive unit 141 described later, and the light receiving sensor 121 is 360 ° around the axis V of the light receiving sensor unit 134, that is, the shaft portion 35 in the height direction. The swirling laser beam L can be received from the direction.

The pedestal 133 is configured to be rotatable coaxially with the axis of the shaft portion 35 by the sensor unit rotation drive unit 141.

In order to rotate the pedestal 133, a sensor unit rotation drive unit 141 is newly provided. The sensor unit rotation drive unit 141 is, for example, a rackland pinion motor drive mechanism, and drives the rotation of the pedestal 133 under the control of the control processing unit 126.

As a result, the light receiving sensor unit 134 is configured to be rotatable around the axis V and vertically movable along the shaft portion 35 as the pedestal 133 rotates.

Further, as shown in FIG. 7, the pedestal 133 is provided with a support member 143 for supporting the shaft portion 35 that supports the light receiving sensor unit 134 on the back side of the light receiving sensor 121 along the shaft portion 35. You may be. The support member 143 supports the shaft portion 35 in a bearing at the upper end of the shaft portion 35. In this way, the stability of the entire robot surveying device is improved, which is advantageous. When the sensor unit elevating drive unit 125 has a ball screw linear motion mechanism, the support member 134 may function as a linear guide.

The control processing unit 126 controls the sensor unit rotation drive unit 141 so that the light receiving sensor 121 can receive the swirling laser light from the 360 ° direction around the axis V. The control will be described.

FIG. 9 is a top view showing how the swirling laser beam R is incident on the light receiving sensor.
As shown in (A), when the rotating laser device 10 and the light receiving sensor 121 are facing each other, the swirling laser light L is incident on the entire surface of the light receiving unit 129.

However, as shown in (B), when the light receiving sensor 121 is tilted to the left with respect to the rotating laser device 10 in FIG. 9, the gray colored portion (corresponding to the light receiving portion 129) on the left side is covered with In this case, the control processing unit 126 controls the sensor unit rotation drive unit 141 so that the light receiving unit 129 receives the light on the entire surface in the direction of the arrow A, the pedestal 133. To the right.

On the other hand, as shown in (C), when the light receiving sensor 121 is tilted to the right with respect to the rotating laser device 10, the gray colored portion (corresponding to the light receiving portion 129) on the right side is a swirling laser. Light L is no longer incident. In this case, the control processing unit 126 controls the sensor unit rotation drive unit 141 to rotate the pedestal 133 counterclockwise in the direction of arrow B so that the light receiving unit 129 receives light on the entire surface.

By doing so, the light receiving sensor 121 always faces the rotating laser device 10, so that the light receiving sensor 121 can receive the swirling laser light L regardless of the direction of the moving body 31, and the axis V The swirling laser beam L from the surrounding 360 ° direction can be received.

Although the preferred embodiments of the present invention have been described above, the above embodiments are examples of the present invention, and these can be combined based on the knowledge of those skilled in the art, and such embodiments are also the present invention. Is included in the range of.

1,1a, 101 Surveying robot system 10 Rotating laser device 20, 20a, 120 Surveying robot 21,121 Light receiving sensor 22 Distance measuring unit 23 Tilt sensor 24 Position acquisition unit 26, 126 Control processing unit 29 Light receiving unit 31 Moving body 45 Notification unit

Claims (5)

A light receiving sensor unit that receives a swirling laser beam that is a height reference emitted from a rotating laser device and detects a light receiving position, and a light receiving sensor unit that includes a distance measuring unit that measures the height of the light receiving sensor.
A mobile body equipped with the light receiving sensor unit and autonomously traveling on a preset path,
An inclination sensor that detects the inclination of the moving body and
A position acquisition unit that acquires the position of the moving body, and
It includes a light receiving sensor, a distance measuring unit, an inclination sensor, and a control processing unit that calculates a ground height profile based on the detection results of the position acquisition unit.
The light receiving sensor is configured to be capable of receiving light from a 360 ° direction around the axis in the height direction and is movable in the height direction, and is characterized in that the swirling laser beam is constantly received at a central position in the height direction. Surveying robot to do. The first aspect of the present invention is characterized in that the light receiving sensor is configured to be able to receive light from the 360 ° direction around the axis by providing the light receiving portion on the entire circumference around the axis in the height direction of the light receiving sensor. The surveying robot described. The surveying robot according to claim 1, wherein the light receiving sensor is configured to be rotatable around the axis of the light receiving sensor so that the light receiving sensor can receive light from a direction of 360 ° around the axis. The control processing unit further includes a notification unit that notifies an abnormality when the light receiving sensor unit cannot receive the swirling laser light at a central position in the height direction. The surveying robot described in any of. * System claim corresponding to claim 1 A rotating laser device that emits a swirling laser beam that serves as a height reference,
A light receiving sensor that receives the swirling laser light and detects the light receiving position, and a light receiving sensor unit that includes a distance measuring unit that measures the height of the light receiving sensor.
A mobile body equipped with the light receiving sensor unit and autonomously traveling on a preset path,
An inclination sensor that detects the inclination of the moving body and
A position acquisition unit that acquires the position of the moving body, and
It includes a light receiving sensor, a distance measuring unit, an inclination sensor, and a control processing unit that calculates a ground height profile based on the detection results of the position acquisition unit.
The light receiving sensor is configured to be able to receive light from a 360 ° direction around the axis in the height direction and to be movable in the height direction, and is characterized in that the swirling laser beam is constantly received at a central position in the height direction. Surveying robot system.