JP2022039648A - Control device and control method for work robot - Google Patents

Abstract

To easily improve work efficiency without affecting work quality by preventing interference and collision of a plurality of work robots by eliminating the need for adjustment as to a work speed when allowing the plurality of work robot to work in one work area Wa.SOLUTION: A control device for a work robot 1 has, in the work robot that forms a work track along a travel route for autonomous traveling, a setting unit that sets a virtual work section Ws for the work robot to work. When setting a first work section Ws(1) for a first work robot 1A to work and a second work section Ws(2) for a second work robot 1B to work, the setting unit sets the second work section so as not to be adjacent to the perimeter of the first work section.SELECTED DRAWING: Figure 5

Description

The present invention relates to a control device and a control method for a work robot.

Conventionally, a work robot that autonomously travels in a work area and performs work such as mowing along a travel path is known (see, for example, Patent Document 1 below). The work robot utilizes a satellite positioning system such as GPS, or detects a reference position such as an electronic tag or a wire installed at the work site and autonomously travels within the set work area.

Japanese Patent No. 5973608

By unmanning the above-mentioned work robot, it is possible to work at night or for a long time, but there is a limit to expanding the work width and increasing the work speed, so a single work robot has high work efficiency (unit). It is difficult to obtain (working time per area). To this end, it is being studied to operate multiple work robots in one work area to improve the total work efficiency.

At this time, if a plurality of work robots working in one work area interfere with each other or collide with each other, the work efficiency cannot be effectively improved. In order to avoid interference or collision of a plurality of working robots, it is conceivable to detect the state of the working robots close to each other and adjust or stop the working speed of one or both working robots. However, if the work speed of the work robot is adjusted or stopped, not only the work efficiency is adversely affected, but also the work quality is deteriorated in mowing work that wants to obtain a high quality finish at a constant work speed. Problems arise.

The present invention has been proposed to deal with such circumstances. That is, when the work of a plurality of work robots is performed in one work area, it is not necessary to adjust the work speed and the like to avoid interference and collision of the plurality of work robots, and the work quality is not affected. It is an object of the present invention to easily improve work efficiency.

In order to solve such a problem, the present invention has the following configurations.

It is a control device of a work robot that forms a work locus along a travel path that autonomously travels, and includes a setting unit for setting a virtual work area in which the work robot performs work, and the setting unit is the first work. When setting the first work area in which the robot works and the second work area in which the second work robot works, the second work area is set so as not to be adjacent to the first work area. A control device for a working robot characterized by setting.

According to the present invention having such a feature, when the work of the work robot is performed in one work area, it is not necessary to adjust the work speed and the like to avoid interference and collision between the work robots, and the work quality is improved. Work efficiency can be easily improved without affecting the work efficiency.

Explanatory drawing of the work robot system. Explanatory drawing of a single working robot ((a) is an explanatory view of a side view, (b) is an explanatory view of a plan view). Explanatory drawing which shows the structure of a work robot system. Explanatory drawing explaining the function of a control device. Explanatory drawing showing a setting example of a work section ((a) shows an example of setting an adjacent section for each work section, and (b) shows an example of setting an adjacent section around the work section). Explanatory drawing of work mode ((a) is a line stripe locus, (b) is a swirl striped locus, (c) is a random locus). Explanatory drawing which shows other setting example of a work area.

Hereinafter, an example of an embodiment of the present invention will be described with reference to the drawings. In the following description, the same reference numerals in different figures indicate parts having the same function, and duplicate description in each figure will be omitted as appropriate.

As shown in FIG. 1, the work robot system 1S is composed of a plurality of work robots 1 (1A, 1B, 1C) and management equipment for managing the work robots 1 (1A, 1B, 1C). The management equipment includes a server 101, a mobile information terminal 102 owned by the user, a charging base 103, and the like, and each equipment can transmit and receive signals to and from the work robot 1 (1A, 1B, 1C) via the network NT. It has become. Further, the plurality of working robots 1 (1A, 1B, 1C) may be capable of transmitting and receiving signals to and from each other without going through the network NT.

The control device for controlling the work robot 1 controls each work robot 1 in the work robot system 1S described above, and the source of the control signal is in each work robot 1, the server 101, and the portable information terminal 102. It may be in any of the charging base 103 and the like.

Each work robot 1 includes a machine body 10 and a traveling unit 2 capable of autonomously traveling, and the machine body 10 is provided with a working unit 3 that performs work along the traveling path of the machine body 10. Further, each work robot 1 includes a control unit 5 that controls a traveling unit 2 and a working unit 3. A communication unit 5A for transmitting and receiving signals is connected to the control unit 5 with the above-mentioned management equipment via the network NT.

As an example, the control unit 5 receives a radio signal transmitted from the GNSS satellite 100 in order to detect the current position of the aircraft 10 by utilizing a satellite positioning system (GNSS; Global Navigation Satellite System) such as GPS. GNSS sensor 6A is connected. In this case, if the RTK-GPS system is adopted, a radio signal is received at a place such as a fixed charging base 103, and the position of each work robot 1 is determined, the position of the moving work robot 1 can be adjusted. It can be measured accurately.

FIG. 2 shows a configuration example of each work robot 1. The traveling unit 2 of the illustrated work robot 1 includes a front wheel traveling unit 2A and a rear wheel traveling unit 2B, and as shown in FIG. 1, is directed toward an arbitrary direction in a work area Wa set in the work site. The aircraft 10 can be autonomously driven. The work area Wa in FIG. 1 is partitioned by a work boundary line Wb, and the work boundary line Wb can be physically sensed by a virtual line or a work robot 1 that can be recognized by each work robot 1 on map information. It is made of various wires.

The machine body 10 of each work robot 1 is provided with a traveling unit 2 and a driving unit 4 for driving the working unit 3. In the example shown in FIG. 2, the drive unit 4 includes a front wheel drive unit 4A and a rear wheel drive unit 4B, respectively, on the left and right sides, and further includes a work drive unit 4C for driving the work unit 3. Further, each work robot 1 includes a battery 11 that serves as a power source for the drive unit 4, the control unit 5, and the like.

The work unit 3 of each work robot 1 performs work such as mowing work, spraying work, and collection work so as to form a work locus along the traveling path of the machine body 10. Hereinafter, the working unit 3 for mowing the grass will be described as an example. In the example shown in FIG. 2, the working unit 3 has a circular working area in a plan view, and the mowing blade (not shown) is rotated around a vertical axis to mow the grass directly under the working unit 3. pay. As a result, when the work unit 3 is driven while the machine body 10 is traveling, a work locus that has been mowed with the diameter of the circular work range in a plan view in the work unit 3 along the travel path of the work robot 1 is created. It is formed.

The body 10 of the work robot 1 is provided with a sensor unit 6. The sensor unit 6 is provided with various detection means such as the GNSS sensor 6A described above in order to autonomously drive the traveling unit 2 or control the driving of the working unit 3. The sensor unit 6 is provided in front of the machine body 10, and the detection signal of the sensor unit 6 is transmitted to the control unit 5.

FIG. 3 shows a configuration example (block diagram) of the work robot system 1S. The drive unit 4, the sensor unit 6, and the battery 11 are connected to the control unit 5 of each work robot 1 (1A, 1B, 1C), and information is input to the communication unit 5A and the control unit 5 described above. The input unit 5B, the storage unit 5C for storing the information input to the control unit 5, and the like are connected.

The sensor unit 6 is provided with the above-mentioned GNSS sensor 6A, an orientation sensor 6B for detecting the traveling direction of the machine body 10, and a boundary detection for physically detecting an electronic tag or a wire installed at a work boundary position. A sensor 6C or the like is provided.

The server 101 is provided with a control unit 50, and the control unit 50 includes a communication unit 51 for connecting the server 101 to the network NT, an input unit 54 for inputting information to the control unit 50, and control. A storage unit 52 that stores information input to the unit 50, a display unit 53 that displays the control status of the control unit 50 or the control unit 5, and the like are connected. The mobile information terminal 102 possessed by the user has the same function as the server 101.

The charging base 103 includes a charging device 103A connected to the battery 11. The charging device 103A, for example, converts the commercial AC power 103B into DC power to charge the battery 11. Further, the charging base 103 can also be provided with a control unit 60 and a communication unit 61 connected to the control unit 60.

The communication unit 5A of the work robot 1, the communication unit 51 of the server 101 or the mobile information terminal 102, and the communication unit 61 of the charging base 103 are connected to each other via the network NT, so that the control unit 5 provided in the work robot 1 is connected. The control unit 50 of the server 101 or the mobile information terminal 102 and the control unit 60 provided in the charging base 103 are in a state of being able to transmit and receive signals (information) to each other, and constitute one integrated control device 5U. ing.

The control of the work robot system 1S is executed by incorporating the program of the function shown in FIG. 4 into the control device 5U. A part or all of the program executed by the control device 5U can be incorporated in the control unit 5 mounted on each work robot 1, and a part or all of the program is incorporated in the control unit 50 of the server 101 or the mobile information terminal 102. Can be incorporated, and a part or all thereof can be incorporated into the control unit 60 provided in the charging base 103. In the management equipment such as the server 101, the portable information terminal 102, and the charging base 103, the equipment in which the essential program is not incorporated in the work robot system 1S can be omitted as appropriate.

The travel control unit P1 in the control device 5U controls the front wheel drive unit 4A and the rear wheel action unit 4B of each work robot 1 to autonomously control the work robot 1 along the travel path set by the setting unit P3. Let it run. Further, the travel control unit P1 controls the work speed (travel speed) of each work robot 1 by controlling the front wheel drive unit 4A and the rear wheel action unit 4B.

The work control unit P2 in the control device 5U controls the work unit 3 under the work conditions initially set by the input from the input unit 5B (54) by controlling the work drive unit 4C of the work robot 1. Further, the work control unit P2 controls the work unit 3 according to the work condition change instruction input by the input unit 5B (54) or the work condition changed according to the setting of the setting unit P3. When the working unit 3 is a mowing working unit, the mowing speed, mowing height, and the like are the above-mentioned working conditions.

The setting unit P3 in the control device 5U includes at least a work area setting means P30 and a traveling route setting means P31.

The work area Ws set by the work area setting means P30 is a small area virtually partitioned in the work area Wa, and one work area Ws is continuous by one work robot 1 (uninterrupted). ) It is a section where a work track is formed.

The work area setting means P30 is, for example, a work area for each of a plurality of work robots 1 (1A, 1B, 1C) based on the set position information which is the position information of the place where the work area is set in the work area Wa. Set Ws. The work area Ws may be set to one area for each work start, or a plurality of work areas, for example, a work area Wa may be divided into a plurality of work areas prior to the start of work. You may.

When the work area setting means P30 of the setting unit P3 sets the work area Ws for each of the plurality of work robots 1 (1A, 1B, 1C), the plurality of work robots 1 (1A, 1B, The set positions of the work compartments Ws are set so as not to be adjacent to each other so that 1C) can avoid interference and collision and perform smooth work.

5 and 6 show an example of the setting. In the example shown in FIG. 5A, the first work section Ws (1) on which the first work robot 1 (1A) works and the second work robot 1 (1B) perform the work. When setting the work section Ws (2), the adjacent section As is set around the first work section Ws (1), and the second work section Ws (2) is set so as not to overlap with the adjacent section As. is doing.

In the example shown in FIG. 5A, a plurality of divisions previously divided with respect to the work area Wa are set, and among the plurality of divisions, the above-mentioned first work division Ws (1) and The second work section Ws (2) and the adjacent section As are set. As the adjacent section As of the example shown in FIG. 5A, a section adjacent to each side of the first work section Ws (1) set in a rectangular shape is selected. Not limited to this example, when the first work area Ws (1) and the second work area Ws (2) are individually set in the work area Wa, as shown in FIG. 5 (b), the first work area Ws (2) is set. An adjacent section As may be arbitrarily set around the work section Ws (1), and a second work section Ws (2) may be set so as not to overlap the adjacent section As.

Further, in the example shown in FIG. 5A, when the third work robot 1 (1C) works in the work area Wa, the third work robot 1 (1C) is the first work robot 1 (1C). It is set not to perform the work during the work of the 1A) and the second work robot 1 (1B). Specifically, when the first work section Ws (1) and the second work section Ws (2) are set in the work area Wa, the third work robot 1 (1C) is charged. It is set to stand by while charging at the base 103.

According to this, it is possible to avoid interference or collision between the work robots 1 when the plurality of work robots 1 work in one work area Wa only by setting the work section Ws and the adjacent section As. As a result, it is possible to easily improve the work efficiency by using the plurality of work robots 1 without adjusting the work time and the work speed of each work robot 1.

Further, when the third work robot 1 is used, one work robot 1 can be used while the two work robots 1 are working while avoiding interference or collision between the plurality of work robots 1. Since charging can be performed, it is possible to efficiently secure the charging time during work.

The travel route setting means P31 in the setting unit P3 sets a travel route for autonomously traveling each work robot 1, and after the work zone setting means 30 sets the work zone Ws as described above, The travel path Rr in the work section Ws is set as shown in FIG. 6, for example.

As shown in FIG. 6, the travel route setting means P31 sets the travel route Rr, so that the work locus Wt is formed in the work section Ws along the travel route Rr. The travel route setting means P31 can set a plurality of work modes for each work section Ws by setting various travel routes Rr. As the working mode, for example, as shown in FIG. 6A, a line-striped locus in which the traveling directions of adjacent linear paths are alternately changed, and as shown in FIG. 6B, the traveling direction of the linear path is set. A swivel stripe-like locus that advances while turning by changing 90 ° (the direction of swirl can be selected from outside to inside as shown and from inside to outside), as shown in FIG. 6 (c). In addition, there is a random locus that travels by randomly changing the traveling direction of the straight path at the end of the work section Ws.

When the work robot 1 is used for mowing work, the mowing pattern can be added to each work section Ws as desired by the user by selecting the work mode, and the random locus shown in FIG. 6 (c) is selected. Can be mowed without a pattern. In particular, in golf courses and driving ranges, the mowing direction of grass (turf) affects how the ball rolls, so the work mode is appropriately selected as the owner likes.

When the travel route setting means P31 of the setting unit P3 sets the travel route Rr in the work section Ws, as shown in FIG. 7, the outer line of the work locus Wt is outside the work section Ws by the set travel path Rr. OL may be formed. Here, when the working unit 3 performs the mowing work, the traveling route Rr is set so that the working unit 3 crosses the boundary line of the working area Ws, and uncut parts are generated near the boundary line of the working area Ws. It is deterring.

In such a case, when the work section setting means P30 sets the adjacent section As described above, the adjacent section As is set so as to include the outer line OL of the work locus Wt. In the example shown in FIG. 7, the outer line OL of the work locus Wt is formed outside the boundary line of the first work section Ws (1) having a rectangular shape, but the outer line OL of the first work section Ws (1) is formed. The adjacent section As includes the adjacent section As adjacent to each side of the first work section Ws (1) and the adjacent section As adjacent to each corner of the first work section Ws so as to include the outline OL. It is set. Then, the second work section Ws (2) is set so as not to overlap with the adjacent section As.

As shown in FIG. 7, by setting the adjacent line As so as to include the outer line OL of the work locus Wt, even if the outer line OL is formed outside the boundary line of the work section Ws, a plurality of lines are formed. It is possible to avoid interference and collision between the work robots 1 and easily improve the work efficiency by using a plurality of work robots 1 without adjusting the work time and work speed of each work robot 1. Can be done.

The map data of the work area Ws required to execute the work is stored in, for example, the storage unit (data storage unit) 5C of the work robot 1. As for this map data, the map data for which the work can be performed is stored in the storage unit 5C for each work. For example, the map data of one work area Ws is used by the work robot 1 after the work of the work area Ws is completed. After returning to the charging base 103, the map data of the storage unit 5C is rewritten to that of the next work area Ws. By doing so, the memory capacity of the storage unit 5C included in the work robot 1 can be reduced. At this time, the map data is transmitted from a base station such as the server 101 or the charging base 103 and stored in the storage unit 5C in the working robot 1.

As described above, according to the control device 5U of the work robot 1 according to the embodiment of the present invention or the control method by the control device 5U, the operation control of the work robot 1 that forms the work locus Wt along the traveling path Rr that autonomously travels. Therefore, a virtual work area Ws in which the work robot 1 performs work is set, and a first work area Ws (1) and a second work robot 1 (1B) in which the first work robot 1 (1A) performs work are set. ) Sets the second work section Ws (2) on which the work is performed, the adjacent section As is set around the first work section Ws (1), and the second work section As does not overlap with the adjacent section As. The second work section Ws (2) is set so as not to be adjacent to the first work section Ws (1) by setting the work section Ws (2) or the like. As a result, when the work of a plurality of work robots 1 is performed in one work area Wa, it is not necessary to adjust the work speed and the like, interference and collision of the plurality of work robots 1 are avoided, and the work quality is affected. Work efficiency can be easily improved without giving.

Although the embodiments of the present invention have been described in detail with reference to the drawings, the specific configuration is not limited to these embodiments, and the design changes, etc. within the range not deviating from the gist of the present invention, etc. Even if there is, it is included in the present invention. Further, each of the above-described embodiments can be combined by diverting the technologies of each other as long as there is no particular contradiction or problem in the purpose and configuration thereof.

1 (1A, 1B, 1C): work robot, 1S: work robot system,
10: Airframe, 11: Battery,
100: GNSS satellite, 101: server, 102: mobile information terminal,
103: Charging base, 103A: Charging device, 103B: Commercial AC power,
2: Running part, 2A: Front wheel running part, 2B: Rear wheel running part, 3: Working part,
4: Drive unit, 4A: Front wheel drive unit, 4B: Rear wheel drive unit, 4C: Work drive unit,
5,50,60: Control unit, 5A, 51,61: Communication unit,
5B, 54: Input unit, 5C, 52: Storage unit, 6: Sensor unit,
6A: GNSS sensor, 6B: directional sensor, 6C: boundary detection sensor,
53: Display unit, 5U: Control device,
P1: Travel control unit, P2: Work control unit, P3: Setting unit,
P30: Work area setting means, P31: Travel route setting means,
Wa: work area, Ws: work area, Wt: work locus, Rr: travel route,
As: Adjacent section, NT: Network, OL: Outer line

Claims (10)

It is a control device for a work robot that forms a work locus along a travel path that travels autonomously.
A setting unit for setting a virtual work area in which the work robot performs work is provided.
The setting unit is
When setting the first work area where the first work robot works and the second work area where the second work robot works.
A control device for a work robot, characterized in that the second work section is set so as not to be adjacent to the periphery of the first work section. The setting unit is
The control device for a work robot according to claim 1, wherein an adjacent section is set around the first work section, and the second work section is set so as not to overlap the adjacent section. The setting unit is
The control device for a work robot according to claim 2, wherein the first work section, the second work section, and the adjacent section are set from a plurality of sections previously divided. The setting unit is
Set the travel route in the work section,
2. The control device for the work robot according to 3. The work robot according to any one of claims 1 to 4, wherein the work of the third work robot is not performed during the work of the first work robot and the second work robot. Control device. It is equipped with a data storage unit that stores the map data of the work area required to execute the work.
The control device for a work robot according to any one of claims 1 to 5, wherein the map data is rewritten after the work of the work area for executing the work is completed. The control device for a work robot according to claim 6, wherein the map data is transmitted from a base station and stored in the data storage unit in the work robot. It is a control method of a work robot that forms a work locus along a travel path that travels autonomously.
Set up a virtual work area where the work robot works,
When setting the first work area where the first work robot works and the second work area where the second work robot works.
A method for controlling a work robot, which comprises setting an adjacent section around the first work section and setting the second work section so as not to overlap the adjacent section. The control method for a work robot according to claim 8, wherein the work robot performs mowing work. The control device for a work robot according to any one of claims 1 to 7, wherein the work robot performs a mowing operation.

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