JP2649859B2 - Automatic inking device - Google Patents

Description

Description: BACKGROUND OF THE INVENTION The present invention relates to an automatic marking device used for automatically marking a flat area such as a concrete floor of a building structure. About.

2. Description of the Related Art In a building such as a building, when a partition wall or other interior work is performed, a drawing for the interior work is generally drawn on a concrete floor surface of the building structure by ink marking.

Conventionally, at the time of such inking, each point designated using a transit is marked by actual measurement, and inking is performed along these marked points.

(Problems to be solved by the invention) However, in the above-described conventional blackout method,
Since the actual measurement and marking work at each designated point are all performed manually, there is a problem that it takes a lot of time and manual work to mark the ink.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described circumstances, and an object of the present invention is to provide an automatic blackout device that can automatically perform blackout of a designated area without requiring any manual operation at low cost.

(Means for Solving the Problems) The present invention will be described with reference to FIG. 1 showing an embodiment. The present invention relates to a reference station 1 installed at a predetermined position in a marking area such as a concrete floor surface. The marking robot 2 which automatically travels along a predetermined travel route in the blackout area, and the reference station 1 and the marking robot 2 which are provided respectively in the marking robot 2 and which always face each other by receiving tracking light transmitted from both. Automatic tracking devices 3 and 4 that perform tracking operations so as to match each other; communication means 5 and 6 installed in each of the automatic tracking devices 3 and 4 for performing data communication between the reference station 1 and the marking robot 2; and one of the automatic tracking devices A distance measuring means 7 for measuring the distance between the reference station 1 and the marking robot 2 by irradiating a light wave from the other automatic tracking device 3 side on a target 8 provided on the base 4; The horizontal angle measuring means 14 for measuring the horizontal deflection angle of the quasi station-side automatic tracking device 3, the vertical angle measuring means 15 for measuring the vertical inclination angle of the reference station-side automatic tracking device 3, and the distance measuring means 7 Calculation control means 13 for calculating the position of the marking robot 1 based on the distance information, the deflection angle information from the horizontal angle measurement means 14 and the tilt angle information from the vertical angle measurement means 15; Marking robot 2 that automatically travels along the road
The direction measuring means 19 for measuring the traveling direction of the vehicle and the marking robot 2 are moved in advance in the blackout area based on the traveling path data set in advance, the traveling direction information from the direction measuring means 19 and the calculated position data. Operation control means 18 for controlling travel along the route, XY blotter 11 installed on the bottom surface of marking robot 1, marking stamper 12 attached to XY blotter 11, and travel control by operation control means 18. When it is determined that the position of the marking robot 2 to be marked is the marking target position on the preset traveling route, the XY blotter 11 is indexed to the marking position, and the marking stamper 12 is operated to operate the concrete floor surface at the indexing position. And a marking control means 18 for making a marking.

The present invention also provides a safety monitoring means 20 for preventing a collision and an overturn against an obstacle when the marking robot 2 travels.
Is provided.

Further, the present invention is characterized in that a remote control means 31 for transmitting a running command to the operation and marking control means 18 of the marking robot 2 by radio to remotely control the marking robot 2 is provided.

(Operation) The automatic tracking device 3 of the reference station 1 and the automatic tracking device 4 of the marking robot 2 perform a tracking operation so as to face each other, so that the distance between the reference station 1 and the marking robot 2 measured by the distance measuring means 7 is increased. Distance and horizontal angle measuring means
The arithmetic control means 13 calculates the position of the marking robot 2 on the marking area starting from the reference station 1 based on the deflection angle from the vertical angle measuring means 15 and the deflection angle from the vertical angle measuring means 15.
Then, the driving and marking control means 18 causes the marking robot 2 to autonomously travel based on the preset traveling route data, traveling direction information and calculated position data. When the marking robot 2 comes to the target position, XY
The plot 11 moves to the marking position and the stamper 12
Operates to perform marking.

Therefore, the marking on the designated marking area can be automatically performed without requiring any manual operation.

In addition, the present invention, by providing the safety monitoring means 20,
The marking robot 2 can safely run autonomously.

Furthermore, in the present invention, by providing the remote control means 31, the marking robot 2 can be remotely controlled by an observer or the like.

Embodiment An embodiment of the present invention will be described below with reference to FIGS.

Fig. 1 is an overall configuration diagram, Fig. 2 is an explanatory diagram showing the relationship between a reference station and a marking robot, Fig. 3 is a bottom view of the marking robot, and Fig. 4 is a side view showing details of a bottom portion of the marking robot. is there.

First, in FIG. 2, reference numeral 1 denotes a reference station installed at a predetermined position in an inking area corresponding to, for example, a concrete floor of a building, and 2 denotes a marking robot that travels vertically and horizontally in the inking area.

The reference station 1 and the marking robot 2 are provided with two-way automatic tracking devices 3 and 4, respectively.

The automatic tracking devices 3 and 4 transmit light waves for tracking toward each other, and by receiving the light waves, each of the automatic tracking devices 3 and 4 in a direction in which the reception level is maximized.
4 is operated in the X, Y, and Z axis directions, whereby the automatic tracking devices 3 and 4 are automatically controlled so that the front faces always face each other.

The automatic tracking devices 3 and 4 are provided with optical communication devices 5 and 6 for performing data communication between them, respectively. Further, the automatic tracking device 3 on the reference station 1 side is provided between the reference station 1 and the marking robot 2. A light wave distance meter 7 for obtaining a distance from the arrival time of the light wave is installed, and a target 8 that reflects a light wave transmitted from the light wave distance meter 7 to the marking robot 2 is installed in the automatic tracking device 4 on the marking robot 2 side. I have.

The marking robot 2 has a driving device 9 and a steering mechanism 10 for automatically moving the marking robot 2 along a traveling route, as shown in FIGS. XY plotter
The XY plotter 11 is provided with a stamper 12 for marking a specified position coordinate on a concrete floor or the like.
Is attached.

 Next, the configuration of FIG. 1 will be described.

In the figure, the reference station 1 includes an arithmetic and control unit 13 for detecting the traveling position of the marking robot 2 in real time and controlling the optical communication device 5, and the arithmetic and control unit 13 is constituted by a computer.

The arithmetic and control unit 13 is connected to an optical communication device 5, an optical distance meter 7, a horizontal angle measuring device 14, and a vertical angle measuring device 15, respectively.

The marking robot 2 includes a main controller 17 that controls the entire marking robot.

The main controller 17 performs optical communication control with the reference station 1, processing for recognizing the position of the marking robot 2, driving processing along the traveling route, safety monitoring processing, and the like, and is composed of a computer.

Main controller 17 includes optical communication device 6 and marking robot 2
Operation and marking control circuit 18, inertia measuring device 19 for measuring the traveling direction of marking robot 2, safety monitoring device 20,
And a storage circuit 21 for storing travel route data of the marking robot 2 and the like.

The lightwave distance meter 7 has a target 8,
That is, the distance to the marking robot 2 is measured from the arrival time of the light wave. The horizontal angle measuring device 14 is a reference point when the automatic tracking device 3 turns horizontally so as to face the automatic tracking device 4 of the marking robot 2. The vertical angle measuring device 15 calculates a tilt angle from a reference point when the automatic tracking device 3 is tilted up and down so as to face the automatic tracking device 4 of the marking robot 2. It is to be measured.

Operation of marking robot 2 and marking control circuit
Numeral 18 controls forward / backward, left / right turning and running stop control of the marking robot 2, start / stop of the driving device 9, and controls the XY plotter 11 and the stamper 12 for marking. Start / stop operation unit 22, forward / backward operation unit 23, steering mechanism 10, brake device 24, X-
The Y plotter 11 and the stamper 12 are connected to each other, and further a wireless receiver 25 that receives a remote command from the outside is connected.

The safety monitoring device 20 of the marking robot 2 is for monitoring the collision prevention with the on-site workers and other obstacles and for preventing the marking robot 2 from falling down. It has a pitching angle detector 28 and a rolling angle detector 29, and these sensors and detectors are connected to the main controller 17 via an interface 30.

Reference numeral 31 denotes a remote control device for remote control of the marking robot 2 by an observer or the like as needed. An operation lever 311 for remotely operating the marking robot 2 and a command signal for converting the operation of the operation lever 311 into a command signal. Generator 3
12 and a radio transmitter 313 for transmitting a signal from the command signal generation circuit 312. The transmission signal of the radio transmitter 313 is received by the receiver 26 of the operation and marking control circuit 18.

Next, the operation of the present embodiment configured as described above will be described in the sixth.
This will be described with reference to the flowchart shown in FIG.

First, in step S1, the X and Y coordinate values x ₀ and y ₀ (see FIG. 5) in the marking area of the reference station 1, the marking position data of the marking area, and the traveling route data of the marking robot 2 are input as initial value data. I do.

Among these, the marking coordinate data and the travel route data are transmitted to the marking robot 2 through the optical communication devices 5 and 6 and stored in the storage circuit 21.

In the next step S2, the automatic tracking devices 3 and 4 of the reference station 1 and the marking robot 2 are set in the operation mode, and the two automatic tracking devices 3 and 4 are set in a bidirectional automatic tracking state in which the front faces face each other.

Next, in step S3, an initial survey of the marking robot 2 is performed.

That is, the distance l between the marking robot 2 and the reference station 1 is measured from the reference station 1 by operating the lightwave distance meter 7 as shown in FIG.
, The deflection angle θ of the automatic tracking device 3 rotated in the horizontal direction about the reference station 1 is measured, and the inclination angle of the automatic tracking device 3 tilted up and down around the reference station 1 is further measured by the vertical angle measuring device 11. The position coordinates (Xn, Yn) of the marking robot 2 at the start point are calculated by measuring and taking in these measurement data into the arithmetic and control unit 13 and performing calculations.

This position coordinate is the coordinate value (start point on the traveling route) of the marking robot 2 when the coordinate (x ₀ , y ₀ ) of the reference station 1 is set to zero.

When the initial survey is completed, the process proceeds to the next step S4, in which the traveling route data is sequentially read from the storage circuit 21 of the main controller 17 and sent to the operation and marking control circuit 18, and the operation and marking control circuit 18 is Is operated to automatically drive the marking robot 2 along the travel route.

When the marking robot 2 travels, the automatic tracking devices 3 and 4 perform tracking operations in both directions so as to face each other, so that the swing angle and the inclination angle of the automatic tracking device 3 on the reference station 1 side also change, and the angle is measured in real time. The distance data with the marking robot 2 is also measured by the lightwave distance meter 7 and taken into the arithmetic and control unit 13. This makes marking robot 2
Is calculated in real time (step S5).

In step S6, the position data of the marking robot 2 calculated in step S5 is compared with a preset marking target position on the traveling route, and it is determined whether the marking target position is the target position.

If it is determined that the position is not the target position, step S7
To determine whether the traveling direction and the moving position of the marking robot 2 match the traveling route, based on the position data calculated by the arithmetic and control unit 13 and the traveling direction data measured by the inertial measuring device 19, If they match, the process moves to step S8, controls the marking robot 2 to go straight, and returns to step S5.

If it is determined in step S7 that the traveling direction and the movement position of the marking robot 2 are deviated from the traveling route, the process proceeds to step S9, in which a fuzzy process is performed to control the steering angle of the marking robot 2, and the marking robot 2 is controlled. 2 to get on the traveling route and return to step S5.

On the other hand, if it is determined in step S6 that it is the target position, the process proceeds to step S10, where the marking robot 2
Pause.

After that, the XY control is performed by the operation and marking control circuit 18.
The plotter 11 is operated to index the stamper 12 at a predetermined marking position on the traveling route (step S1).
1).

The reason for this is that the actual position accuracy of the marking robot 2 by the bidirectional automatic tracking control is in units of centimeters, and position accuracy in units of millimeters cannot be expected.

Therefore, the marking robot 2 is positioned at the approximate target position by the autonomous traveling control, and thereafter, the XY plotter 11 is used.
By operating the stamper 12 at the marking position,
Marking positioning on the order of millimeters becomes possible.

When the XY plotter 11 is indexed to the marking position, the stamper 12 is operated to mark the concrete floor (step S12).

Thereafter, the process proceeds to step S13, where it is determined whether the current position is the final target position of the traveling route.

Here, when it is determined that the position is the final target position, the process proceeds to step S14, where the marking robot 2 is stopped, and the marking operation is completed.

If it is determined in step S13 that the position is not the final target position, the process proceeds to step S15, in which the marking robot 2 is started to travel along the traveling route to the next target position.

The traveling route of the marking robot 2 is set so that the marking robot 2 can travel in a zigzag manner at predetermined intervals in the marking area.

In this embodiment, the bidirectional automatic tracking device is used.
By the autonomous traveling method using 3,4, the marking robot 2 travels along the traveling route while recognizing its own position, and when it reaches the target position, the XY plotter 11 is moved to the marking position. Since the marking is performed by the stamper 12, marking for marking on a concrete floor or the like can be automated and unmanned, and marking can be performed in a wide area in a short time. Accompanying this, the blackout work can be performed even on holidays and at night.

Further, when the safety monitoring device 20 detects an obstacle, the traveling of the marking robot 2 stops, so that it is possible to prevent the marking robot 2 from hitting the obstacle.

In addition, by operating the operation lever 311 of the remote device 31, the marking robot 2 can be remotely controlled, so that an area outside the target can be marked and an emergency stop can be performed manually.

It should be noted that the present invention is not limited to the marking on the concrete floor surface shown in the above embodiment, and it is needless to say that various changes can be made within the scope described in the claims.

(Effects of the Invention) As described above, according to the present invention, it is possible to automatically and unmannedly perform blackout on a designated area and reduce the blackout cost.

In addition, the marking robot can safely run autonomously, security measures against an intruder in the marking area of the marking robot can be ensured, and the marking robot can be remotely controlled.

[Brief description of the drawings]

1 is an overall configuration diagram showing one embodiment of the present invention, FIG. 2 is an explanatory diagram showing the relationship between a reference station and a marking robot in this embodiment, FIG. 3 is a bottom view of the marking robot, and FIG. Is a side view showing the details of the bottom of the marking robot, FIG. 5 is an explanatory diagram showing the positional relationship between the reference station and the marking robot on the X and Y coordinates, and FIG. 6 is a flowchart showing the operation procedure of this embodiment. . In the drawing, 1 is a reference station, 2 is a marking robot, 3 and 4 are automatic tracking devices, 5 and 6 are optical communication devices, 7 is an optical distance meter, 8 is a target, 9 is a driving device, 10 is a steering mechanism, 11 Is XY
Plotter, 12 is stamper, 13 is arithmetic and control unit, 14 is horizontal angle measuring device, 15 is vertical angle measuring device, 17 is main control device, 18 is operation and marking control circuit, 19 is inertia measuring device, 20 is safety monitoring The device 31 is a remote control device.

Continuation of front page (56) References JP-A-62-5122 (JP, A) JP-A-4-7716 (JP, A) JP-A-1-298901 (JP, A) JP-A-2-53115 (JP) , A)

Claims (3)

(57) [Claims] 1. A reference station installed at a predetermined position in an inking area such as a concrete floor, a marking robot that automatically travels along a predetermined traveling route in the inking area, the reference station and a marking robot. Are respectively provided, and an automatic tracking device that performs a tracking operation so as to always face each other by receiving tracking light transmitted from both, and is installed in each of the automatic tracking devices, and data is transmitted between a reference station and a marking robot. Communication means for performing communication; distance measuring means for measuring a distance between a reference station and a marking robot by irradiating a target provided on the one automatic tracking device with light waves from the other automatic tracking device side; and the reference station side. Horizontal angle measuring means for measuring a horizontal deflection angle of the automatic tracking device; Vertical angle measuring means for measuring the inclination angle of the distance, distance information from the distance measuring means, deflection angle information from the horizontal angle measuring means and the position of the marking robot based on the inclination angle information from the vertical angle measuring means Calculation control means for calculating, a direction measuring means for measuring a traveling direction of a marking robot that automatically travels along a travel route in the blackout area, and a travel path data set in advance from the marking robot, based on the direction measurement means. Driving control means for controlling travel along a predetermined travel route in the blackout area based on the traveling direction information and the calculated position data; an XY plotter installed on the bottom surface of the marking robot; A marking stamper attached to a Y plotter, and the marking robot controlled to travel by the operation control means When it is determined that the position is the marking target position on the preset traveling route, the XY plotter is indexed to the marking position, and the marking stamper is operated to mark the concrete floor or the like at the indexing position. Means, and an automatic inking device. 2. The automatic blackout device according to claim 1, further comprising safety monitoring means for preventing a collision and an overturn against an obstacle when the marking robot runs. 3. The automatic blackout device according to claim 1, further comprising remote control means for remotely controlling the marking robot by transmitting a running command to the operation and marking control means of the marking robot by radio.