JP2022032804A - Work vehicle management control system - Google Patents

Abstract

To provide a work vehicle management control system capable of executing safe movement between farm fields when a plurality of work vehicles capable of executing automatic travelling and work are moved between farm fields.SOLUTION: An automatic operation control device of a management control system has an automatic work control mode for controlling automatic work of a plurality of work vehicles in a farm field while preventing the deviation from the shape of the farm field by stopping travelling, and an inter-farm field movement control mode for causing the work vehicle to deviate from part of the shape of the farm field where automatic work is done, and to move to another farm field by automatic travelling, and executes shifting to and cancelling of the inter-farm field movement control mode. In the case where two or more work vehicles of the plurality of work vehicles have shifted to the inter-farm field movement control mode, a remote management operation device operates the automatic operation control device so that when one of the work vehicles is moving between the farm fields, the remaining work vehicles are caused to stop temporarily at the gateway of the farm field, and stand by there.SELECTED DRAWING: Figure 6

Description

The present invention relates to a work vehicle management control system that manages and controls a plurality of work vehicles capable of automatic traveling and work.

Conventionally, it is a management control system that controls an autonomous traveling work vehicle that autonomously travels and works while positioning using a satellite positioning system, and is equipped with a remote control device that can operate an autonomous traveling work vehicle for each field. By transmitting the work area and work content of the field in charge of the autonomous traveling work vehicle for each field through the remote control device, in the predetermined work area of the field in charge of the autonomous traveling work vehicle for each field. There is known a management control system for an autonomous traveling work vehicle that performs predetermined work and monitors the operating state of the autonomous traveling work vehicle for each field (Patent Document 1).
This management control system notifies the work end time of the autonomous traveling work vehicle for each field via the remote control device, and the order in which the vehicle needs to be dispatched from the work end time of the autonomous traveling work vehicle in the work area for each field. Is set, and the vehicle allocation of the autonomous traveling work vehicle having a high order of the vehicle allocation is preferentially executed based on the order of the vehicle allocation.

Japanese Patent No. 6384545

However, in the above-mentioned conventional management control system, the movement of the autonomous traveling work vehicle from one field to another (movement between fields) is loaded onto the transport vehicle to be dispatched from the order of the work end time of the autonomous traveling work vehicle. I'm just teaching you to carry it in. Further, in the conventional management control system, when moving between fields, it seems that it is necessary to manually move the vehicle, which is troublesome, and the trouble is further if a large number of autonomous traveling work vehicles are operated at the same time. It becomes remarkable.

Therefore, the present invention manages a work vehicle capable of safely moving between fields when moving a plurality of work vehicles capable of automatic traveling and work between a field and another field (movement between fields). The purpose is to provide a control system.

The above-mentioned problems of the present invention are solved by the following means.

That is, the invention according to claim 1 is
It has a positioning device (61), a communication device (63), and an automatic operation control device (34) that controls automatic running and work operation, and includes information on the position, shape, and entrance / exit of the field to be worked. Multiple work vehicles (1A, 1B, 1C, 1D, ...) To acquire field information and route information when moving within and between fields, and
By communicating information, each state of the work vehicle (1A, 1B, 1C, 1D, ...) Is grasped and managed, and each automatic operation of the work vehicle (1A, 1B, 1C, 1D, ...) Is performed. A remote management operation device (7) capable of operating the control device (34) and
Equipped with
The automatic operation control device (34) controls the automatic work of the work vehicle (1A, 1B, 1C, 1D, ...) In the field while preventing deviation from the shape of the field by stopping traveling. Automatic work control mode (35) and automatic travel to other fields by deviating from a part of the shape of the field where the work vehicle (1A, 1B, 1C, 1D, ...) Automatically works. It has an inter-field movement control mode (36) that is controlled to be performed by the above, and is controlled to shift and cancel the inter-field movement control mode (36).
In the remote management operation device (7), two or more work vehicles (1A, 1B, 1C) among the work vehicles (1A, 1B, 1C, 1D, ...) Are in the inter-field movement control mode (36). In the case of shifting to, when the one work vehicle (1A) is moving between fields, the remaining work vehicles (1B, 1C) are temporarily stopped at the entrance / exit of the field to be controlled to stand by. It is a work vehicle management control system characterized by operating an automatic driving control device (34).

The invention according to claim 2 is the automatic operation control device (34) in the plurality of work vehicles (1A, 1B, 1C, 1D, ...) In the work vehicle management control system according to claim 1. Transmits the information shifted to the inter-field movement control mode (36) to the remote management operation device (7), and the remote management operation device (7) shifts to the inter-field movement control mode (36). It is characterized by having an inter-field movement monitoring unit (74) that monitors the presence or absence of a work vehicle (1A) that is moving between fields among two or more work vehicles (1A, 1B, 1C).

The invention according to claim 3 is the management control system for the work vehicle according to claim 2, wherein the remote management operation device (7) is a plurality of work vehicles (1A, 1B, 1C, 1D, ... ), In addition to setting and managing the priority of inter-field movement in the inter-field movement control mode (36), when there are two or more work vehicles (1B, 1C) that temporarily stop and stand by at the entrance / exit of the field. It is characterized in that the automatic operation control device (34) is operated so as to perform control for sequentially starting the movement between fields from the higher priority (1B).

The invention according to claim 4 is the management control system for the work vehicle according to claim 3, wherein the remote control operation device (7) has a high priority, and when the work process precedes, the field. It is characterized by applying the case where the waiting time at the doorway is long or the distance required for moving between fields is short.

According to the invention of claim 1, when two or more work vehicles (1A, 1B, 1C) are shifted to the inter-field movement control mode (36), one of the work vehicles (1A) is inter-field. Since the remaining work vehicles (1B, 1C) are managed and controlled to be paused at the entrance / exit of the field and made to stand by while moving, a plurality of work vehicles capable of automatic traveling and work can be moved between fields. It is possible to safely move between fields when moving.

According to the invention of claim 2, the shift from the automatic operation control device (34) in a plurality of work vehicles (1A, 1B, 1C, 1D, ...) To the inter-field movement control mode (36). While receiving, the presence or absence of the work vehicle (1A) moving between fields is monitored among the two or more work vehicles (1A, 1B, 1C) that have shifted to the inter-field movement control mode (36). When moving the work vehicle between fields, safe movement between fields can be reliably performed.

According to the third aspect of the present invention, when there are two or more work vehicles (1B, 1C) that are temporarily stopped and stand by at the entrance / exit of the field, the priority of the inter-field movement in the inter-field movement control mode (36) is set. Since the control is performed to sequentially start the movement between fields from the higher side, it is possible to reliably perform safe movement between fields when moving a plurality of work vehicles between fields.

According to the invention of claim 4, when the remote management operation device (7) has a high priority, the work process precedes, the waiting time at the entrance / exit of the field is long, or the movement between fields is required. Since the case where the distance is short is applied, safe inter-field movement can be performed more appropriately, with less waste, and more efficiently when moving a plurality of work vehicles between fields.

It is a schematic diagram which shows the management control system of the work vehicle which concerns on embodiment. It is a functional block diagram which shows the management control system of FIG. It is a schematic diagram which shows an example of each state of the tractor at the time of being controlled by the automatic work control mode and the inter-field movement control mode in the management control system of FIG. It is a schematic diagram which shows the structure of the outer peripheral storage point which specifies the shape of a field, the entrance / exit, etc., and the route information in a field. It is a flowchart which shows the control example about the inter-field movement control mode in the management control system of FIG. It is a flowchart which shows the control example at the time of moving a plurality of work vehicles between fields by the management control system of FIG.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

As shown in FIGS. 1 to 3, the work vehicle management control system according to the present embodiment automatically controls the positioning device 61, the communication device 63, and the automatic traveling and work (automatic driving) operations. A plurality of work vehicles 1A, 1B, 1C, 1D, ... It is possible to grasp and manage each state of the work vehicle 1A, 1B, 1C, 1D, ..., And to operate each automatic operation control unit 34 of the work vehicle 1A, 1B, 1C, 1D, ... It is equipped with a remote management operation device 7, and manages and controls a plurality of work vehicles 1A, 1B, 1C, 1D, ..., Which enables them to be moved between fields.
Here, the movement between fields means moving from one field 9 to another field 9. Further, in FIG. 1, only one of a plurality of work vehicles 1A, 1B, 1C, 1D, ... Is shown as a representative, and the others are omitted.

First, the plurality of work vehicles 1A, 1B, 1C, 1D, ... Applied to this management control system is a tractor 10 as an example of a work vehicle. The plurality of tractors 10A, 10B, 10C, 10D, ... In the present embodiment are all capable of automatic running and work (automatic operation mode), and are manually operated by the operator. The tractor is capable of running and working (manual operation mode), and its automatic operation mode and manual operation mode can be switched by operating the operation mode selector switch 59 (FIG. 2, SW: switch).

Further, the plurality of tractors 10A, 10B, 10C, 10D, ... (Hereinafter, abbreviated as a plurality of tractors 10 unless necessary) are all traveling vehicle bodies as shown in FIG. A working machine 27 for performing the required work in the field 9 is attached to the rear portion. FIG. 1 exemplifies a rotary tiller as a working machine 27, which is vertically attached by a three-point link mechanism 28 or the like. The work machine 27 is not limited to this, and may be any work machine that can be attached to the tractor 10 and is used for work performed in the field 9, for example, work of a sowing machine, a mower, or the like. It may be a machine. Further, regarding the working machine 27, if there are tractors 10 working in the same field 9 among a plurality of tractors 10, different types of working machines 27 will be mounted, but the working machine 27 is not necessarily limited to this.

Further, as shown in FIG. 1, in each of the plurality of tractors 10, a front wheel 11 that functions as a steering wheel is arranged at the front portion of the traveling vehicle body, and a rear wheel 12 that functions as a driving wheel is arranged at the rear portion of the traveling vehicle body. The engine 14 is mounted in the engine room (space) covered with the bonnet 13 at the front of the traveling vehicle body. Further, each of the plurality of tractors 10 is an example of a drive wheel via a transmission shaft (drive axle) 17 after appropriately decelerating the rotational power of the engine 14 mainly by the transmission 16 in the transmission case 15. It is configured to transmit at least a part of the rotational power to the wheel 12 to the working machine 27 via the PTO shaft 18 protruding from the rear end of the transmission case 15.

Further, each of the plurality of tractors 10 is provided with substantially the same cabin 20 at the upper part of the traveling vehicle body. The driver's seat 21 is arranged inside the cabin 20, and the steering wheel 22 is arranged in front of the driver's seat 21. In the vicinity of the driver's seat 21 and the steering wheel 22, various operation levers such as the forward / reverse switching lever 23, various switches (not shown), a display panel for displaying necessary information, and the like are arranged. Further, various pedals such as a clutch pedal 24a, a brake pedal 24b, and an accelerator pedal (not shown) are arranged in the lower part of the cabin 20.

Further, as shown in FIG. 2, each of the plurality of tractors 10 is provided with substantially the same control device 30 that comprehensively controls the operation of the tractor 10 and the operation of the working machine 27.
In FIG. 2, only the control device 30 of one tractor 10A is specified on behalf of each control device 30 in the plurality of tractors 10, and the others are omitted.

The control device 30 is composed of a computer including, for example, a processing device such as a CPU (Central Processing Unit), a storage device such as a ROM (Read only Memory), a RAM (Random Access Memory), and an HDD (Hard Disk Drive), and an input device. The processing device processes information based on the control program, data, and detection information stored in the storage unit 31 of the ROM or HDD, so that the control information is transmitted to the necessary control target. ing.

Further, each of the control devices 30 has a vehicle control unit 32 that controls the operation of the tractor 10 in the vehicle body, a work machine control unit 33 that controls the operation of the work machine 27 in the tractor 10, and a tractor as control functions thereof. It has an automatic operation control unit 34, which is an example of an automatic operation control device that controls each operation of automatic travel and automatic work (automatic operation) related to the 10 and the work machine 27. Strictly speaking, the vehicle control unit 32, the work machine control unit 33, and the automatic operation control unit 34 are similarly present in each control device 30 in the plurality of tractors 10.

Of these, the vehicle control unit 32 is composed of, for example, a vehicle ECU (Electronic Control Unit) that controls the operation of the engine 14 and the traveling operation. The vehicle ECU may be divided into an engine ECU that exclusively controls the operation of the engine 14 and a traveling ECU that exclusively controls the traveling operation.

Further, as shown in FIG. 2, the vehicle control unit 32 targets the vehicle control drive unit 40, which is connected to the control device 30 so as to be able to transmit information. The vehicle control drive unit 40 automatically steers, for example, an operation adjusting device for the engine 14, a changing device for changing the number of shift stages and forward / backward movement of the speed change device 16, and a steering device 19 for changing the steering direction (turning angle) of the front wheels 11. It is a control device, a working part of a clutch device (not shown), a working part of a braking device, and the like.

The vehicle control unit 32 controls the operation of the vehicle control drive unit 40 while acquiring the detection information detected by various sensors 50 on the vehicle side that detect the state necessary for the control.
The various sensors 50 on the vehicle side include, for example, the rotation speed of the engine 14, the traveling speed, the turning angle of the steering wheel 22, the steering direction of the steering device 19, the operation lever, the operation pedal, the inclination of the traveling vehicle body, the fuel remaining amount sensor 52, and the like. It is a plurality of sensors that detect each state of.

Next, the work machine control unit 33 is composed of, for example, a work machine ECU or the like. The working machine ECU is mounted on the working machine 27 applicable to ISOBUS, which is a communication standard for agricultural aircraft. Further, as shown in FIG. 2, the work machine control unit 33 targets the work machine control drive unit 48, which is connected to the control device 30 so as to be able to transmit information. Examples of the working machine control drive unit 48 include a switching device for the PTO shaft 18, a speed change device thereof, an elevating device 49 for the working machine 27, an electric motor, and the like.

The work machine control unit 33 controls the operation of the work machine control drive unit 48 while acquiring the detection information detected by various sensors 57 on the work machine side that detect the state necessary for the control. The various sensors 57 on the working machine side are, for example, a plurality of sensors that detect each state such as the rotation speed of the PTO shaft 18, the elevating position of the working machine 27, the driving speed, and the tilling depth.

Next, the automatic operation control unit 34, as a part of the control function of the control device 30, performs each operation during automatic traveling or automatic work related to the tractor 10 and the working machine 27 based on a program, various data, and the like. It is the part that functions to control. The automatic driving control unit 34 is actually configured to execute control in cooperation with the vehicle control unit 32 and the work equipment control unit 33, respectively.
The automatic operation control unit 34 operates based on the detection information that the above-mentioned operation mode changeover switch 59 in each tractor 10 has been switched to the automatic operation mode.
The details of the automatic operation control unit 34 will be described later.

Further, as shown in FIGS. 1 and 2, the positioning device 61, the communication device 63, and the obstacle sensor 65 are related to the fact that each of the plurality of tractors 10 has an automatic operation control unit 34. It is equipped with a camera 66, a display device 67, a buzzer 68, a voice reproduction device 69, and the like.

The positioning device 61 is a device that positions the self-positions of each tractor 10 that is a plurality of work vehicles 1 and acquires them as position information.
The positioning device 61 is configured by, for example, a device using a GNSS (Global Navigation Satellite System), receives radio waves from a navigation satellite by a receiving antenna 62, and individually acquires GNSS coordinates at predetermined time intervals. It is designed to acquire location information on the earth. The receiving antenna 62 is provided at a predetermined portion of the work vehicle 1, and is provided on, for example, the upper surface of each cabin 20 in the tractor 10 in the present embodiment.
Further, the positioning device 61 is configured to install a base station (for example, RTK-GNSS (Real Time Kinematic-GNSS) base station or the like) at a required place such as near the field 9 to obtain more accurate position information. You may.

The communication device 63 is a device capable of data communication with a device such as a remote control operation device 7. As the communication method, for example, a communication network technology such as the Internet, a mobile communication system such as 4G, and a short-range wireless communication technology such as Wi-Fi and Bluetooth (registered trademark) (Bluetooth) are applied.
Further, the communication device 63 may be configured to relay communication by installing a base station at a required place such as the vicinity of the field 9.

The obstacle sensor 65 is a sensor that detects obstacles existing around the tractor 10 when traveling, and is composed of, for example, an ultrasonic sensor, an infrared sensor, and the like. The camera 66 is capable of shooting a moving image in which the surroundings of the tractor 10 and the state of the tractor can be visually confirmed while the tractor 10 is traveling. The obstacle sensor 65 and the camera 66 are arranged not only at one place on the traveling vehicle body but also at a plurality of places where obstacle detection and photographing are required.

The display device 67 displays necessary information to be transmitted to the operator sitting in the driver's seat 21, and is composed of, for example, a liquid crystal display panel or the like. The buzzer 68 mainly emits an alarm sound for calling attention to a person in the vicinity of the tractor 10. The voice reproducing device 69 mainly reproduces a voice notifying a person around the tractor 10 that automatic traveling or work is performed, and is composed of, for example, a voice generating device, a speaker, or the like.

Then, as shown in FIGS. 2 and 3, the automatic operation control unit 34 controls the automatic work of the plurality of tractors 10 in the field 9 while preventing the deviation from the shape of the field 9 by stopping the traveling. Automatic work control mode 35 for automatic work, and inter-field movement control mode 36 for controlling movement of a plurality of tractors 10 to another field 9 by deviating from a part of the shape of the field 9 for automatic work. Information acquisition unit 37 that acquires field information including information such as the position, shape, entrance / exit 91, etc. of the field 9 to be worked, work information in the field 9, and route information when moving within the field 9 and between the fields 9. have.

The information acquisition unit 37 is configured to acquire information necessary for controlling automatic operation, such as the field information and work information of the field 9 scheduled to be worked, and the route information, via an information acquisition means such as a communication device 63. ing. The information acquired by the information acquisition unit 37 is temporarily stored in the storage unit 31.
As the field information, work information, and route information to be acquired, the information stored or created in the remote control operation device 7 is used.

Of the field information, the shape information of the field 9 is preset in association with the map information for each field 9 to be automatically operated by the tractor 10 managed and controlled by the management control system, as shown in FIG. It is the information of the shape obtained by connecting the outer peripheral storage points Pa with a line.
Further, as shown in FIG. 4, the information of the entrance / exit 91 of the field 9 is the information of the portion of the outer peripheral storage point Pa indicated by the entrance / exit storage point Pb designated as the position corresponding to the entrance / exit 91 of the field 9. .. The entrance / exit 91 is not limited to the one in which the entrance and the exit are shared as shown in FIG. 4 and the like, and also includes the one in which the entrance and the exit are separate and independent.
Further, the work information is information about the work created based on the work contents and conditions planned in advance by the user in the device such as the remote control operation device 7.

Further, the route information in the field 9 is, for example, a work traveling route at the time of automatic work shown by a two-dot chain line with the reference numerals Rs1 to Rs6 in FIG. 4 and a two-dot chain line with the reference numerals Rt1 to Rt5. It is composed of a turning travel path for moving between the work travel paths Rs shown. Reference numerals L and R attached to the numbers in FIG. 4 indicate the left direction (L) and the right direction (R) when the tractor 10 in FIG. 4 travels forward.

Further, the route information for moving between the fields 9 is, for example, a road (mainly an agricultural road) connecting the movement route Rm in the field 9 shown in FIG. 3 between the source field 9 and the destination field 9. It is composed of 95 traveling paths Rr. In FIG. 3, six fields 9A to 9F are exemplified, and the portion existing between the fields 9A to 9C and the fields 9D to 9F is a road (farm road) 95. In FIG. 3, there is a boundary such as a shore between adjacent fields 9.

The automatic work control mode 35 is a function of controlling the operation when a plurality of tractors 10 automatically work in the field 9 where the work is scheduled. Strictly speaking, the operation of automatic work includes the operation of automatic driving.
In the automatic operation control unit 34, when the operation mode changeover switch 59 (FIG. 2) is switched to the automatic operation mode, the automatic work control mode 35 is selected as the initial setting.

In the automatic work control mode 35, the tractor 10 that has entered the field 9 to be worked is according to the work information of the field 9 acquired by the information acquisition unit 37 and the route information in the field 9 (work travel route Rs, turning travel route Rt, etc.). While automatically traveling in the field 9, the working machine 27 mounted on the tractor 10 is operated to control the automatic work.
As a result, automatic work is carried out. Reference numeral Ps shown in FIG. 3 and the like indicates a work start position during automatic work, and reference numeral Pe indicates a work end position during automatic work.
Incidentally, the movement and approach of the plurality of tractors 10 to the first field 9 where the work is scheduled are performed by the manual operation (mode) of the operator.

Further, in the automatic work control mode 35, when the tractor 10 is performing automatic work in the field 9, the tractor 10 deviates from the planned route from the position information of the tractor 10 and is surrounded by the shape of the field 9 (enclosed by the outer peripheral storage point Pa). When a movement that is likely to deviate from the outside of the shape) is detected, the tractor 10 is suspended. This prevents the tractor 10 from deviating from the shape of the field 9.
The tractor 10 at the time of being temporarily stopped is then returned to the shape of the field 9 by automatically moving backward or steering so as to be returned to the planned route.

Next, the inter-field movement control mode 36 is a function of controlling the operation when the plurality of tractors 10 automatically move from the field 9 to the next field 9 to be worked by automatically traveling between the fields. From the viewpoint of approaching the expression of the automatic work control mode 35, the inter-field movement control mode 36 can be paraphrased as an automatic traveling control mode at the time of inter-field movement.

In principle, the automatic operation control unit 34 shifts to and cancels the inter-field movement control mode 36 based on the detection information that the position information obtained from the positioning device 61 of the tractor 10 reaches a specific position in the field 9. It is controlled to do.
The specific position at this time is, for example, the work end position Pe of the field 9 that has been automatically worked at the time of transition, and the work start position Ps of the destination field 9 at the time of release. As an exception, the transition to the inter-field movement control mode 36 can be performed by operating an operating device such as the remote control operating device 7, as will be described later.

Further, when there is a tractor that has shifted to the inter-field movement control mode 36 among the plurality of tractors 10, the automatic operation control unit 34 transmits the information that the tractor 10 has shifted to the inter-field movement control mode 36 to the remote management operation device 7. It is designed to send. Further, the transition to the inter-field movement control mode 36 may be configured to be transmitted to a cloud computing system described later.

Further, the automatic operation control unit 34 controls so as to allow only deviation when the tractor 10 passes through the doorway 91 which is a part of the shape of the field 9 when the mode shifts to the inter-field movement control mode 36. When the tractor 10 tries to deviate from a part other than the doorway 91 which is a part of the shape of the field 9, the tractor 10 is controlled to be stopped in the same manner as in the control in the automatic work control mode 35.
As a result, in the inter-field movement control mode 36, the tractor 10 can move between fields through the entrance / exit 91 of the field 9, and the tractor 10 deviates from the shape of the field 9 in the field 9. Is prevented.

In the inter-field movement control mode 36, the route information (movement within the field 9) acquired by the information acquisition unit 37 from the field 9 where the plurality of tractors 10 are automatically worked to the field 9 where the next work is scheduled is performed. It is controlled so that a part of the field 9 and the road 95 between the fields are automatically driven according to the route Rm and the traveling route Rr of the road 95).
As a result, automatic running is carried out when moving between fields.

Further, in the inter-field movement control mode 36, when the tractor 10 reaches the doorway 91 when moving to the doorway 91 in the field 9 of the moving source, the tractor 10 is temporarily stopped, and the field 9 of the moving destination is controlled. It is configured to control the temporary stop of the tractor 10 when the tractor 10 reaches the doorway 91.

Further, in the control thereof, the automatic driving control unit 34 includes detection information of various sensors 50 on the vehicle side, various sensors 57 on the working machine 27 side, and position information of the positioning device 61 as information necessary for automatic driving. , Information such as communication information obtained from the communication device 63 is used. Further, in the control, as information necessary for automatic operation, detection information from the obstacle sensor 65, video information from the camera 66 (information obtained by image processing), and the like are also used.
The automatic driving control unit 34 has a function of detecting the presence or absence of obstacles that hinder automatic driving and work from the detection information from the obstacle sensor 65 and the image information from the camera 66, and the automatic driving control unit 34 has a function of detecting the presence or absence of obstacles that hinder automatic driving and work. When the existence is recognized, the automatic operation of the tractor 10 is controlled to be stopped in an emergency.

On the other hand, the remote control operation device 7 is a device capable of grasping and managing each state of the plurality of tractors 10 by communication of information and operating each automatic operation control unit 34 in the plurality of tractors 10. Is.

As shown in FIG. 2, the remote management operation device 7 is a communication device 76 capable of communicating information with each communication device 63 in a plurality of tractors 10, including a management control device 71 configured by the computer or the like. It also includes an input device 77 such as a keyboard, a touch panel, and a switch (SW), and a display device 78 such as a liquid crystal panel and a lamp. The management control device 71 has a storage unit 72 composed of a ROM, an HDD, and the like, and an information acquisition unit 73 that acquires necessary information from a plurality of tractors 10 through a communication device 76.
Such a remote control operation device 7 is composed of a device such as a computer (server), and is installed in a facility such as a remote control center or a field management building located at a place some distance from the field 9. Will be done.

Further, the remote management operation device 7 is also configured as a device capable of cloud computing between the communication device 76 and each communication device 63 in the plurality of tractors 10. Cloud computing is a system constructed to manage information and perform necessary processing using a computer (server) or storage connected to a communication network such as the Internet.
For the connected computer (server) and storage, for example, a computer dedicated to cloud computing installed in a predetermined location such as a remote management center or an external data center, an external storage device, etc. are applied, but the remote management operation is performed. A part of the device 7 may be constructed as a cloud computing system.

The management control device 71 performs necessary information processing based on the program and data stored in the storage unit 72 and the information obtained by the communication device 76, and the operation target via the communication device 76. A process of transmitting necessary control information to each of the plurality of tractors 10 is performed.
The storage unit 72 stores necessary information such as field information about the field 9 scheduled to be worked on by the plurality of tractors 10, route information regarding each route R in automatic running and work by the plurality of tractors 10. Further, the storage unit 72 also stores a route generation program or the like that generates each route R related to the plurality of tractors 10.

The information acquisition unit 73 acquires necessary information such as position information, switching between the automatic work control mode and the inter-field movement control mode, and various states from the plurality of tractors 10 through the communication device 76. Further, if the information transmitted from the plurality of tractors 10 is stored in the cloud computing system, the information acquisition unit 73 acquires the information via the cloud computing.

Further, the information acquisition unit 73 is configured to classify and sequentially manage at least the following five types of states (1) to (5) as information regarding the states of the plurality of tractors 10.
・ State (1)… Moving on the route in the field 9 ・ State (2)… Stopping in the middle of the route in the field 9 ・ State (3)… Waiting for movement between fields in the field 9 ・ State (4)… Field Moving on a route outside 9 ・ State (5)… Stopped in the middle of a route outside field 9

As illustrated in FIG. 3, the state (1) is a state in which the field 9 is automatically moved along a route such as a work travel route Rs. The state (2) is a state in which an emergency stop is made while traveling along the route in the field 9 (obstacle detection, refueling response, etc.). This state (2) is set, for example, when the obstacle detection information or the small amount of detection information of the fuel remaining amount sensor 52 or less is obtained from the obstacle sensor 65 or the camera 66. The state (3) is a state in which it is necessary to stop and stand by before leaving the field 9 of the moving source due to the movement between fields by the movement control mode 36 between fields.
Further, the state (4) is a state in which the vehicle is automatically traveling outside the field 9 (road 95) along a route such as the travel route Rr by the inter-field movement in the inter-field movement control mode 36. This state (4) is set, for example, when the position information that the tractor 10 has advanced to the outside of the field 9 (road 95) from which the tractor has moved is obtained during the movement between fields. The state (5) is a state in which an emergency stop is made during the state (4) (obstacle detection, etc.).

In FIG. 3, the tractor 10D that is automatically working in the field 9A is in the state (1), and the tractor 10C that is urgently stopped in the middle of the automatic work in the field 9D is in the state (2). It is exemplified that the tractors 10B, 10C, and 10A that are stopped and waiting at each entrance / exit 91 of 9E when moving between fields are in the state (3). Further, in FIG. 3, the tractor 10A automatically traveling on the road 95 when moving from the field 9E to the field 9B is in the state (4), and the tractor 10A automatically travels from the field 9D to the road 95 for the inter-field movement. It is illustrated that the tractor 10C that is urgently stopped on the way is in the state (5).

These states (1) to (5) are classified based on the position information and the like acquired by the information acquisition unit 73 from the plurality of tractors 10. Further, the classification of the states in the plurality of tractors 10 may be performed in parallel in the automatic operation control unit 34 of each tractor 10. In this case, the automatic operation control unit 34 of the plurality of tractors 10 transmits the changed state to the information acquisition unit 73 or the cloud computing system each time the state changes, and the management control device 71 sends the changed state to the information acquisition unit 73 or the cloud computing system. Information may be transmitted to the automatic operation control unit 34 of each tractor 10 for sharing.

Then, as illustrated in a part of FIG. 3, the remote control operation device 7 is one in the case where two or more of the tractors 10B and 10C out of the plurality of tractors 10 have shifted to the inter-field movement control mode 36. Control to suspend the remaining work vehicles tractors 10B and 10C at the entrance / exit 91 of the source field 9 (for example, 9C and 9D) while the tractor 10A, which is one work vehicle, is moving between fields. It is configured to operate the automatic operation control unit 34 to do so.
In this case, when moving between fields in the inter-field movement control mode 36, when moving out of the field 9 of the moving source and automatically traveling on the road 95 toward the field 9 of the moving destination. Is.

Further, as shown in FIG. 2, the remote control operation device 7 is currently moving between fields among the two or more tractors 10 that have shifted to the inter-field movement control mode 36 as a control function of the management control device 71. It has an inter-field movement monitoring unit 74 that manages the presence or absence of the tractor 10.

As a result, in the remote control operation device 7, when two or more tractors 10B and 10C are shifted to the inter-field movement control mode 36, the inter-field movement monitoring unit 74 has a tractor 10A that is moving between fields. When there is information on the above, in the remote control operation device 7, the tractors 10B and 10C, which are the remaining work vehicles, are moved to the entrance and exit of the field 9 (9C, 9D) from which the remaining work vehicles are moved, via the control of the automatic operation control unit 34 as described above. It is designed to be paused at 91 and put on standby.

On the other hand, in the remote control operation device 7, when a plurality of tractors 10B and 10C are shifted to the inter-field movement control mode 36, the information that the inter-field movement monitoring unit 74 does not have the tractor 10 moving between fields. When there is, if there are two or more tractors 10 that have transitioned to the inter-field movement control mode 36, the inter-field movement of the tractor 10A that has transitioned earlier is started.
Further, when the number of the transferred two or more tractors 10 is three or more, the inter-field movement is sequentially started according to the priority of the inter-field movement as described later.

In FIG. 3, the field 9D also has another tractor 10C that is in the state (3) by temporarily stopping at the entrance / exit 91 after shifting to the inter-field movement control mode 36, and actually moves between fields. It is shown that there are two or more tractors 10B, 10C that shift to the control mode 36, pause at the doorway 91, and stand by. Therefore, FIG. 3 illustrates a case where there are a total of three or more tractors 10 (10A, 10B, 10C) that have transitioned to the inter-field movement control mode 36.

Further, the remote control operation device 7 sets and manages the priority of inter-field movement in the inter-field movement control mode 36 of the plurality of tractors 10 to be managed, and temporarily stops at the entrance / exit 91 of the field 9 to stand by. When there are two or more tractors 10 to be operated, the automatic operation control unit 34 is configured to control the start of the inter-field movement in order from the one having the higher priority of the inter-field movement.

The priority of inter-field movement is appropriately set by a remote monitor who uses the remote control operation device 7, a user who plans to work with a plurality of tractors 10, and the like, and the priority is set appropriately. Is assigned to each tractor 10 and managed.
In the remote control operation device 7, as a case where the priority of the movement between fields is high, for example, when the work process of the action performed in the field 9 precedes, when the waiting time at the entrance / exit 91 of the field 9 is long, the movement between fields is performed. At least one is applied when the required distance is short.
When a plurality of high cases (conditions) are applied as a case where the priority of movement between fields is high, the priority of the multiple high cases may also be set.

As shown in FIG. 2, the management control device 71 has a priority determination unit 75 for determining whether the priority of movement between fields is high or low as a part of the control function. The priority determination unit 75 determines whether the priority is high or low based on necessary information such as the state, position information, route information, work information, etc. of the tractor 10 that has shifted to the inter-field movement control mode 36 acquired by the information acquisition unit 73. It is configured to determine.

Further, as shown in FIG. 2, the remote management operation device 7 manually forces the automatic operation control unit 34 of the control device 30 in the tractor 10 into the inter-field movement control mode 36 as a part of the input device 77. Switch between manually executing (resuming) or automatically executing the inter-field movement control mode transition switch 77a of the inter-field movement control mode transition switch and the tractor 10 in which the automatic traveling during the inter-field movement is temporarily stopped. It has a manual / automatic changeover switch 77b for executing inter-field movement, an emergency stop switch (not shown) for forcibly stopping in an emergency, and the like.

As shown by the chain double-dashed line in FIG. 1, such a remote control operation device 7 is used by a user who uses the tractor 10 to automatically travel and work at a place away from the tractor 10. A remote control terminal 70 that performs a required operation by communicating information about the operation may be used in combination. The remote control terminal 70 is configured as a terminal device such as a tablet type, for example.

Then, the management control system of the plurality of tractors 10 (10A to 10D) according to the present embodiment operates as follows.

Here, first, the basic common control operation of the automatic work control mode 35 and the inter-field movement control mode 36 in the automatic operation control unit 34 of the target tractor 10 managed and controlled by the management control system will be described. .. Further, here, as illustrated in FIG. 3, the case where four tractors 10A to 10D perform the first work in the fields 9A, 9C, 9D, 9E will be described.
By the way, the automatic driving for automatic driving and work is assumed to be unmanned driving in which the driver does not ride in the driver's seat 21 of the tractor 10, but manned driving in which the driver rides in the driver's seat 21 may be used. ..

First, the four tractors 10A to 10D move to any of the fields 9A, 9C, 9D, and 9E to be worked by the operator's manual operation, enter each field 9, and then operate. The operation mode changeover switch 59 is switched from the manual operation mode to the automatic operation mode by a person. If the autonomous driving is unmanned, at this point the operator gets off the driver's seat 21 of each tractor 10 and leaves the tractor 10.

In the management control system, as shown in FIG. 5, it is determined in the automatic operation control unit 34 whether or not the automatic work control mode 35 is selected (step 10: S10), and when the automatic work control mode 35 is selected. The four tractors 10A to 10D execute automatic work in the fields 9A, 9C, 9D, and 9E of the moving source, respectively (S11). FIG. 3 shows a case where the automatic work by the tractors 10A to 10D is started at a time different from each other.
At this time, the selection of the automatic work control mode 35 is determined by the information that the operation mode changeover switch 59 is switched to the automatic operation mode is acquired by the information acquisition unit 37.

As a result, the tractors 10A to 10D are moved from the work start positions Ps of the moving fields 9A, 9C, 9D, and 9E to the fields 9A, 9C, 9D, and 9E via the vehicle control unit 32 in the automatic work control mode 35. While being controlled to automatically travel in each field 9 according to each route information (working travel route Rs, etc.), the working machine 27 is controlled to perform automatic work via the working machine control unit 33.

Subsequently, in the management control system, the tractors 10A to 10D automatically working in the automatic operation control unit 34 have reached the work end position Pe, which is an example of a specific position in the fields 9A, 9C, 9D, 9E of the moving source. Whether or not it is determined (S12).

When it is determined in step 12 that the work end position Pe has been reached, the automatic operation control unit 34 is automatically shifted from the automatic work control mode 35 to the inter-field movement control mode 36 (S13), and then the inter-field movement. The automatic traveling of the tractors 10A to 10C shifted to the control mode 36 is started (S14).
At this time, the tractors 10A to 10C are shifted to the inter-field movement control mode 36, so that the tractors 10A to 10C can move between fields from the source field 9A to the destination field 9E. Further, the remaining tractor 10D at this time has not reached the work end position Pe and is in the state (1) of moving in the field 9A.

At this time, whether or not the work end position Pe has been reached is determined by whether or not the position information obtained from the positioning device 61 and acquired by the information acquisition unit 37 has reached the work end position Pe in the work path. .. At this time, in the tractors 10A to 10C, when the work end position Pe is reached, the automatic work control mode 35 is controlled so that the work machines 27 are stopped and raised by the elevating device 49 to the position when not in use. To.

Further, after the tractors 10A to 10C at this time reach the work end position Pe, the work end positions Pe of the fields 9C, 9D, and 9E of the movement source are via the vehicle control unit 32 in the inter-field movement control mode 36. It is controlled to automatically travel in each field 9 toward each entrance / exit 91 according to each route information (movement route Rm in the field) in the fields 9C, 9D, and 9E. FIG. 3 shows a case where the tractor 10B automatically travels from the work end position Pe in the field 9C toward the entrance / exit 91 of the field 9C along the route Rm in the field.

Subsequently, in the management control system, whether or not the tractors 10A to 10C when moving between fields in the automatic operation control unit 34 have reached the entrance / exit 91, which is a part of the shape of the fields 9C, 9D, 9E of the moving source, respectively. It is determined (S15).
When it is determined that the doorway 91 has been reached in this step 15, the automatic traveling of the tractors 10A to 10C during the movement between fields is interrupted and temporarily stopped (S16).

At this time, the tractors 10A to 10C are controlled by the automatic work control mode 35 via the vehicle control unit 32 so that the automatic traveling is interrupted and temporarily stopped at the entrance / exit 91. Further, the tractors 10A to 10C at this time are in the state of waiting for movement between fields (3) in the field 9.

Subsequently, in the management control system, it is determined whether or not the automatic operation control unit 34 is instructed to execute (restart) the movement between fields (S17).

In this management control system, since the manual / automatic changeover switch 77b for executing the inter-field movement in the input device 77 of the remote management operation device 7 is switched to the automatic side, the instruction to execute the inter-field movement is a remote management operation. After a predetermined time has elapsed from the device 7, the data is automatically transmitted to the corresponding tractors 10A to 10C, respectively. In this case, in the corresponding tractors 10A to 10C, the instruction for executing the inter-field movement is received by each communication device 63 and sent to each automatic operation control unit 34, respectively.

By the way, when the manual / automatic changeover switch 77b for executing the movement between fields is switched to the manual side, the instruction for executing the movement between fields is given by the switching operation of the changeover switch 77b in the remote control operation device 7. ..
In this case, the remote observer who operates the remote control operation device 7 determines whether or not it is safe for the tractor 10 to move between fields from the entrances and exits 91 of the fields 9C, 9D, and 9E from which the tractor 10 is moved. After confirming, it is possible to give an instruction to execute the movement between fields. As a result, the tractor 10 in which the execution of the inter-field movement is manually instructed is given an opportunity for safety confirmation, and the safer inter-field movement becomes possible.

When it is determined in step 17 that the instruction to execute the inter-field movement is instructed, the automatic traveling during the inter-field movement is started and restarted in the corresponding tractors 10A to 10C (S18). Here, it is assumed that the tractor 10A is first (earliest) instructed to execute the inter-field movement.
At this time, the tractor 10A advances to the road 95 through the entrance / exit 91 of the field 9E of the moving source via the vehicle control unit 32 in the inter-field movement control mode 36, and then the route information (road) at the time of inter-field movement. It is controlled to automatically travel along the traveling route Rr) of 95 and move toward the destination field 9B. As a result, automatic traveling on the road 95 when moving between fields is performed. Further, the tractor 10A at this time is in the state (4) of being moving on the route outside the field 9.

Subsequently, in the management control system, the automatic operation control unit 34 determines whether or not the tractor 10A moving between fields has reached the entrance / exit 91, which is an example of a part of the shape of the destination field 9B (S19). ).

When it is determined in step 19 that the entrance / exit 91 of the destination field 9B has been reached, the automatic traveling of the tractor 10A during the movement between fields is interrupted and temporarily stopped (S20), and then the destination field 9B is reached. It is made to enter inside by automatic running (S21).

At this time, the tractor 10A is controlled by the automatic work control mode 35 via the vehicle control unit 32 so that the automatic traveling is interrupted and temporarily stopped at the entrance / exit 91.
Further, the tractor 10A at this time is moved through the vehicle control unit 32 in the automatic work control mode 35, for example, after a certain period of time has elapsed from the time of temporary stop, the movement between fields is resumed, and the entrance / exit 91 in the destination field 9B is resumed. It is controlled to pass through and enter the field 9B.

Subsequently, in the management control system, the automatic operation control unit 34 determines whether or not the tractor 10A entering the destination field 9B has reached the work start position Ps, which is an example of a specific position of the field 9B. (S22).

When it is determined in step 22 that the work start position Ps has been reached, the automatic work control mode 35 controls the tractor 10A via the vehicle control unit 32 so that the automatic traveling between fields is completed, and the automatic operation is performed. In the control unit 34, the inter-field movement control mode 36 is canceled and automatically shifts to the automatic work control mode 35 (S23).
At this time, the tractor 10A is in a state where the inter-field movement control mode 36 is canceled and the inter-field movement is completed.

As described above, according to this management control system, since the automatic operation control unit 34 has the inter-field movement control mode 36 based on the automatic traveling, the tractor 10 capable of automatic traveling and work is moved between the fields. (For example, moving the tractor 10A from the field 9D to the field 9B) can be easily performed by automatic traveling.

Next, the operation of the management control system when moving a plurality of tractors 10 between fields will be described.
Here, it is assumed that the three tractors 10A to 10C can move between fields by shifting to the inter-field movement control mode 36.

First, in the management control system, information on the transition from the tractors 10A to 10C to the inter-field movement control mode 36 is transmitted to the information acquisition unit 73 in the management control device 71 of the remote control operation device 7, and is shown in FIG. The information acquisition unit 73 continuously receives the transition information and manages the transfer information while using the storage unit 72 (step 30: S30).

At this time, information such as position information and state information is sequentially transmitted to the information acquisition unit 73 of the remote control operation device 7 from all the tractors 10 to be controlled including the tractors 10A to 10C. Further, in this management control system, information such as location information and status information including migration information is transmitted to a cloud computing system (hereinafter, may be abbreviated as "cloud"), and the cloud is transmitted to the cloud. The information acquisition unit 73 of the remote management operation device 7 can acquire the information via the remote management operation device 7.

Subsequently, when the management control device 71 receives the information shifted to the inter-field movement control mode 36, whether or not the number of tractors 10 shifted to the inter-field movement control mode 36 is 2 (units) or more by using the information as a trigger. Is determined (S31). At this time, the management control device 71 determines by referring to the information on the number of tractors 10 that have transmitted the information acquired and accumulated by the information acquisition unit 73 to the inter-field movement control mode 36.

When it is determined in step 31 that the number of tractors 10 shifted to the inter-field movement control mode 36 is one (unit) instead of two or more, the remote management operation device 7 first determines the inter-field movement control mode 36. The automatic operation control unit 34 of the tractor 10A is operated so that one tractor 10A that has been transferred to the tractor 10A controls to start the movement between fields (S32). As a result, the tractor 10A is moved between fields while being controlled by the movement control mode 36 between fields as described above.

In this case, it is determined whether or not the movement of the tractor 10A between fields is completed (S33), and when it is determined that the movement is completed, the operation by the remote control operation device 7 is continued.
At this time, when the tractor 10A reaches the work start position Ps in the destination field 9B, the inter-field movement control mode 36 is canceled and the automatic work control mode 35 is entered. It is determined that the information acquisition unit 73 acquires the information shifted to the work control mode 35.

On the other hand, if it is determined in step 31 that there are two or more tractors 10 that have transitioned to the inter-field movement control mode 36, it is determined whether or not there is a tractor 10 that is moving between fields at that time. S34). This determination is made with reference to the information collected by the inter-field movement monitoring unit 74 in the management control device 71.
At this time, if there is no tractor 10 during inter-field movement, the inter-field movement of the tractor 10A that first shifts to the inter-field movement control mode 36 is executed to the end (S32, S33), as in the above case.

When it is determined in step 34 that there is a tractor 10 moving between fields, the remote management operation device 7 moves the remaining tractors 10B and 10C that have not moved between the fields to the entrances and exits 91 of the fields 9C and 9D from which they are moved. Each of the automatic operation control units 34 of the tractors 10B and 10C is operated (S35) so that the control for suspending and waiting is performed.
As a result, as shown in FIG. 3, the tractors 10B and 10C are temporarily stopped at the entrances and exits 91 of the fields 9C and 9D, respectively, and stand by. At this time, the tractors 10B and 10C are in the state of waiting for movement between fields (3) in the field 9.

As a result, the management control system is managed so that two or more tractors 10 do not move between fields at the same time. Further, in this management control system, as illustrated in FIG. 3, there is no overlapping portion between the travel path Rr for inter-field movement in the tractor 10A and the travel route Rr for inter-field movement in the tractor 10B. Even if there is, when there is a tractor 10A moving between the preceding fields, the other tractor 10B is put on standby for movement between the fields.

Subsequently, it is determined whether or not there is one (unit) of tractors 10 waiting at the entrance / exit 91 of the field 9 (S36).

If it is determined in step 36 that there is only one tractor 10 on standby, it is determined whether or not the preceding inter-field movement by the tractor 10A has been completed (S37).
In this case, there were tractors 10A and 10B that shifted to the inter-field movement control mode 36 with a time lag from one tractor 10 on standby, but one of the tractors 10A decided to start the inter-field movement first. In such a case, the other tractor 10B becomes one in standby.

At this time, if it is determined that the preceding inter-field movement has been completed, the automatic operation control unit 34 of the tractor 10B is operated so that the tractor 10B, which has next transitioned to the inter-field movement control mode 36, controls to start the inter-field movement. (S38). As a result, the tractor 10B is executed for subsequent inter-field movement while being controlled by the inter-field movement control mode 36 as described above. At this time, the tractor 10B moves from the source field 9C to the field 9F as shown in FIG.

In this case, it is determined whether or not the subsequent inter-field movement of the tractor 10B is completed (S39), and when it is determined that the tractor 10B is completed, the operation by the remote control operation device 7 is continued.
At the end of the subsequent inter-field movement at this time, when the tractor 10B reaches the work start position Ps in the destination field 9F, the inter-field movement control mode 36 is canceled and the mode shifts to the automatic work control mode 35. It is determined that the information acquisition unit 73 acquires the transferred information.

On the other hand, when it is determined in step 36 that there are two or more tractors 10 on standby instead of one, the priority of inter-field movement in the two examples of the tractors 10B and 10C is compared (S40). ).
In this case, as for the comparison of the priority of the movement between fields, the priority determination unit 75 in the management control device 71 selects the higher one by comparing the priorities of the corresponding tractors 10B and 10C managed by the information acquisition unit 73. It is done by doing.
Specifically, for example, when the remote control operation device 7 has a high priority and the waiting time at the entrance / exit 91 of the field 9 is long, the tractor 10B temporarily waits at the entrance / exit 91 of the field 9C. If the elapsed time from the start is relatively longer than that of the tractor 10C, it is determined that the priority of the tractor 10B is higher than the priority of the tractor 10C.

Subsequently, the remote control operation device 7 operates the automatic operation control unit 34 of the tractor 10B so that the control for starting the movement of the tractor 10B having a relatively higher priority between fields is performed (S41).
As a result, the tractor 10B is moved between fields while being controlled by the movement control mode 36 between fields as described above. At this time, as shown in FIG. 3, the tractor 10C is continuously stopped at the entrance / exit 91 of the field 9D at the moving source and is placed in a standby state. As a result, in this management control system, the tractor 10B and the tractor 10C are managed and controlled so as not to start the inter-field movement (movement outside the field) at the same time.

Subsequently, it is determined whether or not the inter-field movement of the tractor 10B, which has a high priority and has started the inter-field movement in advance, has been completed (S42).
At this time, if it is determined that the preceding inter-field movement has been completed, the inter-field movement of the tractor 10C or the like corresponding to the second or higher priority of the inter-field movement is sequentially started (S43). The subsequent tractor 10 having a lower rank continues to stop and wait for the start of the inter-field movement at the entrance / exit 91 of the original field 9 until the inter-field movement is completed.

Finally, the remote control operation device 7 determines whether or not all the inter-field movements of the tractors 10 determined to be two or more on standby in step 43 have been completed (S44). At this time, when it is determined that the last movement between fields has been completed, the operation by the remote control operation device 7 is continued.

As described above, according to this management control system, when a plurality of tractors 10A, 10B, 10C are transferred to the inter-field movement control mode 36, the remaining tractor 10A remains when the one tractor 10A is moving between fields. Since the tractors 10B and 10C of the above are managed and controlled to be temporarily stopped at the entrance / exit 91 of the fields 9C and 9D to stand by, the tractors moving between the fields are always kept at one, and as a result, the tractors are always kept at one. , Safe inter-field movement can be performed when a plurality of tractors 10 capable of automatic traveling and work are moved between fields.

Further, in this management control system, when there are two or more tractors 10 that are temporarily stopped at the entrance / exit 91 of the field 9 and stand by for the movement between fields, the priority of the movement between fields in the movement control mode 36 between fields is set. Since the control is performed to sequentially start the movement between fields one by one (unit) from the higher side, it is possible to efficiently perform safe movement between fields when moving a plurality of tractors 10 between fields.

The present invention is not limited to the configuration example of the management control system according to the above embodiment, and as illustrated below, an appropriately modified configuration is adopted as long as it does not deviate from the gist of the present invention. It is possible to do.

In the management control system according to the above embodiment, if it is found that two or more tractors 10 are moving on a route outside the field 9 (4), any of the tractors 10 is moved between fields. It is preferable to adopt a configuration in which the automatic driving control unit 34 is operated so as to control the emergency stop on the road 95. This may be caused by an unexpected information acquisition error, other operation error, or the like.
If such an emergency stop configuration is adopted, if there is an overlapping portion in the traveling route of inter-field movement, there is a risk that the corresponding tractors 10 may collide with each other on the road 95 or interfere with each other's course. It can be prevented from occurring.

In addition, when adopting this emergency stop configuration, information that two or more tractors 10 are in the state (4) is transmitted to the remote management operation device 7 directly or via the cloud to the remote monitor. It may be configured to notify.
Further, in this case, after the notification, the information that the remote management operation device 7 has two or more tractors 10 in the state (4) in the other tractors 10 other than the corresponding tractor 10 via the cloud. Is transmitted, and if another tractor 10 is in the state of working in the field 9 (1) at that time, the control is automatically performed to unconditionally put the tractor into the state of waiting (3) at the entrance / exit 91 of the field 9. It is preferable to adopt a configuration in which the operation control unit 34 is operated.
As a result, it is possible to prevent another tractor 10 from starting to move between fields and automatically traveling on the road 95 outside the field 9.

When the remote control terminal 70 is used in combination with the remote control operation device 7, when the manual / automatic changeover switch 77b for executing inter-field movement in the remote control operation device 7 is switched to the manual side, the remote control terminal 70 is carried remotely. After confirming whether it is safe for the observer (user) to move between fields with priority among the two or more tractors 10 waiting at the entrance / exit 91 of the field 9 of the moving source, the corresponding tractor 10 is selected. It may be configured so that an instruction to execute the movement between fields can be issued from the remote control terminal 70 by communication of information.

In addition, in the management control system according to the above embodiment, when the automatic operation control unit 34 shifts to the inter-field movement control mode 36, the detection information of the fuel remaining amount sensor 52 is equal to or less than a predetermined low remaining amount value. In addition, the tractor 10 (for example, the tractor 10C shown in FIG. 3) may be controlled to be stopped at the entrance / exit 91 of the field 9D at the moving source to perform the refueling operation.
In this case, the automatic operation control unit 34 may be configured to control the tractor 10 moving between fields to notify the remote control operation device 7 or the like that refueling work is required. Further, in this case, when the detection information of the fuel remaining amount sensor 52 exceeds a predetermined high remaining amount value due to the refueling work, the control for restarting the movement between fields may be performed.
When this configuration is adopted, for example, it is possible to prevent the tractor 10 from stopping due to running out of fuel during the movement between fields, and it is possible to reliably move between fields to the end. become.

The present invention is not limited to a work vehicle for agricultural work such as a tractor 10, but can also be applied to a work vehicle for performing various other works.

1A, 1B, 1C, 1D ... Multiple work vehicles 7 ... Remote control operation device 9 ... Fields 10A, 10B, 10C, 10D ... Multiple tractors (example of multiple work vehicles)
34 ... Automatic operation control unit (an example of automatic operation control device)
35 ... Automatic work control mode 36 ... Inter-field movement control mode 61 ... Positioning device 74 ... Inter-field movement monitoring unit 91 ... Doorway (an example of a part of the shape of the field)

Claims (4)

It has a positioning device (61), a communication device (63), and an automatic operation control device (34) that controls automatic running and work operation, and includes information on the position, shape, and entrance / exit of the field to be worked. Multiple work vehicles (1A, 1B, 1C, 1D, ...) To acquire field information and route information when moving within and between fields, and
By communicating information, each state of the work vehicle (1A, 1B, 1C, 1D, ...) Is grasped and managed, and each automatic operation of the work vehicle (1A, 1B, 1C, 1D, ...) Is performed. A remote management operation device (7) capable of operating the control device (34) and
Equipped with
The automatic operation control device (34) controls the automatic work of the work vehicle (1A, 1B, 1C, 1D, ...) In the field while preventing deviation from the shape of the field by stopping traveling. Automatic work control mode (35) and automatic travel of the work vehicle (1A, 1B, 1C, 1D, ...) To another field by deviating from a part of the shape of the field where automatic work is performed. It has an inter-field movement control mode (36) that is controlled to be performed by the above, and is controlled to shift and cancel the inter-field movement control mode (36).
In the remote management operation device (7), two or more work vehicles (1A, 1B, 1C) among the work vehicles (1A, 1B, 1C, 1D, ...) Are in the inter-field movement control mode (36). In the case of shifting to, when the one work vehicle (1A) is moving between fields, the remaining work vehicles (1B, 1C) are temporarily stopped at the entrance / exit of the field to be controlled to stand by. A work vehicle management control system characterized by operating an automatic driving control device (34). Each of the automatic operation control devices (34) in the plurality of work vehicles (1A, 1B, 1C, 1D, ...) Transfers the information shifted to the inter-field movement control mode (36) to the remote control operation device (7). ), And
The remote control operation device (7) determines whether or not there is a work vehicle (1A) that is moving between fields among two or more work vehicles (1A, 1B, 1C) that have shifted to the inter-field movement control mode (36). The management control system for a work vehicle according to claim 1, further comprising a field-to-field movement monitoring unit (74) for monitoring. The remote management operation device (7) sets and manages the priority of inter-field movement in the inter-field movement control mode (36) of the plurality of work vehicles (1A, 1B, 1C, 1D, ...). At the same time, when there are two or more work vehicles (1B, 1C) that are temporarily stopped and stand by at the entrance / exit of the field, the automatic control is performed to sequentially start the movement between fields from the higher priority (1B). The work vehicle management control system according to claim 2, wherein the operation control device (34) is operated. The remote control operation device (7) applies a case where the work process precedes, a case where the waiting time at the entrance / exit of the field is long, or a case where the distance required for moving between fields is short, as the case where the priority is high. The work vehicle management control system according to claim 3.

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