KR102548019B1 - Path generation device and work vehicle - Google Patents

Abstract

The route generating device of the present invention can specify a travel region (F) in which the aircraft (2) autonomously travels, and generate in advance a travel path (P) of the aircraft (2) in the travel region (F). A path creation unit 55 that can be located, and a control unit 4 capable of instructing travel of the aircraft 2 along the travel path P. The route generating unit 55 generates the travel route P based on a start position S at which the aircraft 2 starts traveling and an end position E at which the aircraft 2 ends traveling In addition, after generation of the travel route P, a position change of either one of the start position S and the end position E can be accepted to correct the travel route P after the generation. .

Description

Path generation device and work vehicle {PATH GENERATION DEVICE AND WORK VEHICLE}

The present invention relates to a path generating device for generating a travel path for autonomous travel of a machine, and a work vehicle capable of autonomous travel.

Conventionally, a control device is mounted on a master work vehicle that runs manned and a slave work vehicle that autonomously travels unmanned, respectively, enabling wireless communication between the work vehicles, and the slave work vehicle runs in parallel with the master work vehicle (倂走). ) is well known (see, for example, Patent Document 1). In this case, the operator operates the remote control device while operating the master work vehicle to autonomously drive the slave work vehicle, so that the master work vehicle and the slave work vehicle can run side by side to perform, for example, agricultural work in a field. there is.

In addition, in order to efficiently and easily perform agricultural work on the field, a travel route is created so that straight travel, turning near the boundary, and resumption of straight travel following turning are repeated in order, and the agricultural work vehicle follows the travel route. Techniques for enabling autonomous driving are known (for example, see Patent Literatures 2 and 3).

Japanese Patent Publication No. 2001-507843 Japanese Unexamined Patent Publication No. 2004-8053 Japanese Unexamined Patent Publication No. 2011-254704

By the way, in the prior art, after setting the start position where the aircraft starts traveling and the end position where the aircraft travel ends, and then generating the travel route based on these positions, the start location, the end location and the travel route are 1 It has a relationship of one-to-one correspondence (the relationship between the starting position and the ending position and the traveling route is fixed). So, for example, if there is a deep groove near the starting position of the pavement and there is a risk of hindering the movement of the aircraft, to change the starting position of the driving route, reset the starting position and ending position to create a new entire driving route. Since you have to go through the process of recreating it from scratch, there was room for improvement considering the setting workability.

In addition, in the prior art, when the autonomous driving (agricultural work) of the agricultural vehicle along the driving route is terminated before reaching the previously set end position, the driving route used during the previous autonomous driving is reused at the next autonomous driving Since it cannot be done, it is necessary to execute the operation of creating a driving route again for the unworked area in the pavement. Therefore, for example, in the case of carrying out agricultural work over multiple days in a large-scale field, etc., it takes time and effort to create a travel route each time, and there is room for improvement in view of the setting workability.

Further, in the prior art described above, the slave work vehicle starts autonomous travel at the time when the operator operates the autonomous travel start using the remote control device in parallel with the master work vehicle's operation. In addition, the slave work vehicle stops autonomous travel at the time when the operator operates the autonomous travel stop using the remote control device in parallel with the operation of the master work vehicle. Therefore, at the point in time when the operator wants to start or stop the autonomous driving of the slave work vehicle, the operator must use the remote control device to perform an autonomous driving start operation or an autonomous driving stop operation. In addition, there was a problem that the operation of the remote control device for the slave work vehicle was cumbersome.

The present invention has been made in view of the above current situation, and has as a technical problem to provide a path creation device that can easily create a travel path without recreating it.

In addition, the present invention has been made in view of the above current situation, and is technically to provide a work vehicle capable of starting or stopping autonomous driving at an appropriate time point after performing an autonomous driving start operation or an autonomous driving stop operation. making it a task

The present invention provides a path creation unit capable of specifying a travel area in which the aircraft autonomously travels and generating a travel path of the aircraft in the travel area in advance; A path generating device having a control unit capable of generating the traveling path based on a start position at which the aircraft travels and an end position at which the aircraft travels end, and the travel After generation of the route, it is possible to accept a location change of any one of the starting position and the ending position, and the driving route after the generation can be corrected.

In the route generating device, the route generating unit, when accepting the position change, accepts a predetermined position on the generated travel route as a new start position or a new end position, and is capable of correcting the generated driving route. You can do it by saying that there is.

In the route generating device, in the case of accepting the position change, the route generating unit accepts a predetermined position within the travel area and outside the generated travel route as a new start position or a new end position, and It may be said that the later travel route can be corrected.

Further, the path creation device according to the present invention includes a path generator capable of specifying a travel area in which the machine autonomously travels and generating a travel path of the machine in the travel area, and a part of the travel path. A unit route setting unit capable of setting the unit route of the aircraft and a control unit capable of instructing driving of the aircraft along the unit route are provided.

In the route generating device, the route generating unit may generate a route including a plurality of work routes and a plurality of turning circuits as the driving route, and the unit route setting unit may generate a route including a plurality of work routes and a plurality of turning circuits, The position of the end of the work path is set to a start position at which the machine travels start and an end position at which the machine travels end in the unit path.

In the route generating device, the route generating unit may generate a route including a plurality of work routes and a plurality of turning circuits as the driving route, and the unit route setting unit may generate a route including a plurality of work routes and a plurality of turning circuits, It is forbidden to set the intermediate position of the work path to the start position at which the machine starts traveling and the end position at which the machine travels end in the unit route.

In addition, the present invention is a work vehicle having a body and a control unit for autonomously driving the body along a preset travel path, wherein the control unit initiates autonomous driving of the body when a driving start condition is satisfied. That is, the gas can be waited until

The work vehicle includes a communication unit capable of communicating with another control unit included in the other work vehicle, and the driving start condition is the current position of the other work vehicle obtained from the other control unit to the control unit through the communication unit. It may be assumed that includes the fact that is a predetermined position.

In addition, the present invention is a work vehicle having a body and a control unit for autonomously traveling the body along a preset travel path, wherein the control unit stops the self-driving of the body when a driving stop condition is satisfied. It may be said that the running of the body can be continued until

The work vehicle includes a positional information acquisition unit capable of acquiring positional information of the machine, and the travel stop condition includes that the current position of the machine based on the positional information is a predetermined position.

According to the present invention, a path creation unit capable of specifying a travel area in which the aircraft autonomously travels and generating a travel path of the aircraft in the travel area in advance, and instructing travel of the aircraft along the travel path. A path generating device having a control unit capable of generating the travel path based on a starting position at which the aircraft travels and an end position at which the aircraft travels end, After the creation of the travel route, a position change in either of the start position and the end position can be accepted to correct the travel route after the creation. Even when there is a risk of impediment to travel, the previously created travel route can be changed only by changing the position of either one of the start position and the end position without recreating the previously created travel route itself from scratch. It can be useful and corrected. Therefore, the setting workability of the travel route can be improved, the operator's workload is reduced, and the travel route adapted to the paved conditions can be generated.

According to the present invention, a path creation unit capable of specifying a travel area in which the aircraft autonomously travels and generating a travel path of the aircraft in the travel area, and a part of the travel path as a unit path of the aircraft. Since it is provided with a unit path setting unit that can be set and a control unit that can instruct the running of the aircraft along the unit path, therefore, for example, even when agricultural work is executed over multiple days in a large-scale field, as described above A plurality of unit routes can be set by using the created driving route itself without recreating it from scratch. Therefore, for example, considering the use time of the aircraft, etc., the travel range of the aircraft can be easily distinguished, and the operator's workload is reduced. In addition, it becomes easy to organize the work process of a day, for example.

According to the present invention, a work vehicle having a body and a control unit for autonomously traveling the body along a preset travel route, wherein the control unit initiates autonomous driving of the body when a driving start condition is satisfied. Since the machine can be kept on standby until , it becomes possible to reserve the start of autonomous driving of the work vehicle, and after performing an operation to start autonomous driving of the work vehicle in advance, a desirable time point at which the conditions for starting the travel are met (for example, the above When a work vehicle and another work vehicle are paralleled, the autonomous driving of the work vehicle can be started when the other work vehicle arrives at a carrying position, etc.). There is no need for an operator to perform a self-driving start operation in accordance with the timing at which autonomous driving of the work vehicle is to be started, and the driving operability of the work vehicle is improved.

In addition, according to the present invention, a work vehicle having a body and a control unit for autonomously traveling the body along a preset travel path, wherein the control unit stops the self-driving of the body, when the driving stop condition is met. Since the machine continues to run until the work vehicle is stopped, it becomes possible to reserve the autonomous travel stop of the work vehicle, and after performing the self-travel stop operation for the work vehicle in advance, a desirable time point at which the travel stop condition is satisfied (eg For example, when the work vehicle arrives at the opening of the pavement, etc.), autonomous driving of the work vehicle may be stopped. In accordance with the timing of stopping the autonomous driving of the work vehicle, there is no need for an operator to perform a self-driving stop operation, and the driving operability of the work vehicle is improved.

1 is an overall side view of a robot tractor in an embodiment.
2 is a plan view of the robot tractor.
3 is a functional block diagram of a robot tractor.
Fig. 4 (a) is a diagram explaining the setting of the travel path P for the inclined pavement area F and the work area W, (b) is an explanatory diagram when the turning radius is reduced after correction, ( c) is an explanatory diagram in the case of enlarging the turning radius after correction.
5 is an overall side view of an unmanned tractor and a manned tractor.
6 is a functional block diagram of an unmanned tractor and a manned tractor.
7 is a screen diagram of a remote control device during autonomous driving of an unmanned tractor.
8 is a flowchart showing an example of autonomous driving start reservation control.
Fig. 9 is a diagram explaining a parallel operation at the time of execution of autonomous driving start reservation control.
10 is a flowchart showing another example of autonomous driving start reservation control.
11 is a flowchart showing an example of autonomous driving suspension reservation control.
Fig. 12 is a diagram for explaining a parallel operation at the time of execution of autonomous driving suspension reservation control.
13(a) to (d) are screen views of the remote control device for explaining an example of correction of a travel route in the case of changing the starting position outside the travel route.
14(e) to (h) are screen views of the remote control device for explaining an example of correction of a travel route in the case of changing an end position outside the travel route.
15(i) to (l) are screen views of the remote control device for explaining an example of travel route correction in the case of changing the starting position on the travel route.
16(m) to (p) are screen views of the remote control device for explaining examples of travel route correction in the case of changing the end position on the travel route.
17(a) (b) is a screen diagram of a remote control device for explaining an example of division of a traveling route.

EMBODIMENT OF THE INVENTION Below, embodiment which actualized this invention is described based on drawing. First, a robot tractor 1 (hereinafter sometimes simply referred to as "tractor") as an example of a work vehicle according to the present invention will be described. A tractor 1 includes a body 2 that autonomously travels on a field. The body 2 is provided with a work machine 3 denoted by dashed lines in FIGS. 1 and 2 so as to be attachable or detachable. The working machine 3 is used for agricultural work. As this working machine 3, there are various working machines such as a cultivator, a plow, a fertilizing machine, a mowing machine, and a seeding machine. there is. The base body 2 is configured to be able to change the height and posture of the work implement 3 mounted thereon.

The configuration of the tractor 1 will be described with reference to FIGS. 1 and 2 . As shown in Fig. 1, a body 2, which is a body of a tractor 1, is supported at its front by a pair of left and right front wheels 7, 7, and at its rear is supported by a pair of left and right rear wheels 8, 8. is supported by The front wheels 7, 7 and the rear wheels 8, 8 constitute the traveling portion.

A bonnet 9 is arranged at the front of the body 2. Inside this bonnet 9, the engine 10 which is a driving source of the tractor 1, a fuel tank (not shown), etc. are accommodated. Although this engine 10 can be comprised by the diesel engine, for example, it is not limited to this, You may configure by the gasoline engine, for example. In addition, as a drive source, you may use an electric motor in addition to an engine or instead of this.

Behind the bonnet 9, a cabin 11 in which an operator rides is disposed. Inside the cabin 11, a steering wheel 12 for steering operation by the operator, a seat 13 on which the operator can sit, and various operating devices for performing various operations are mainly formed. However, the agricultural work vehicle is not limited to the one with the cabin 11, but may not be provided with the cabin 11.

Although illustration is abbreviate|omitted, as said operating apparatus, a monitor device, a throttle lever, a main speed lever, a lift lever, a PTO switch, a PTO shift lever, and several hydraulic shift levers etc. are mentioned, for example. These operating devices are disposed near the seat 13 or near the steering wheel 12 .

The monitor device is configured to be able to display various types of information about the tractor 1. The throttle lever sets the rotational speed of the engine 10 . The main transmission lever changes and operates the transmission ratio of the transmission case 22 . The lifting lever is for raising and lowering the height of the work machine 3 mounted on the body 2 within a predetermined range. The PTO switch connects/disconnects power transmission from the rear end side of the transmission case 22 to the PTO shaft (power take-out shaft) protruding outward. That is, when the PTO switch is in the ON state, power is transmitted to the PTO shaft so that the PTO shaft rotates and the work machine 3 is driven, while when the PTO switch is in the OFF state, power to the PTO shaft is cut off and the PTO shaft rotates. Without doing so, the work machine 3 is stopped. The PTO shift lever is used to change the power input to the work machine 3, and specifically, to change the rotational speed of the PTO shaft. The hydraulic shift lever switches and operates the hydraulic external take-off valve.

As shown in Fig. 1, a chassis 20 constituting the skeleton is formed in the lower part of the body 2. The chassis 20 is composed of a body frame 21, a transmission case 22, a front axle 23, a rear axle 24, and the like.

The body frame 21 is a support member at the front of the tractor 1, and supports the engine 10 directly or through an anti-vibration member or the like. The transmission case 22 changes power from the engine 10 and transmits it to the front axle 23 and the rear axle 24 . The front axle 23 is configured to transmit power input from the transmission case 22 to the front wheels 7 . The rear axle 24 is configured to transmit power input from the transmission case 22 to the rear wheels 8.

As shown in FIG. 3 , the tractor 1 is a control unit for controlling the operation of the aircraft 2 (forward, backward, stop and turn, etc.) and the operation of the implement 3 (elevation, drive and stop, etc.) A control device (4) is provided. To the control device 4, a common rail device 41 as a fuel injection device, a transmission device 42, a lift actuator 44, and the like are electrically connected, respectively.

The common rail device 41 injects fuel into each cylinder of the engine 10 . In this case, by controlling the opening and closing of the fuel injection valves of the injectors for each cylinder of the engine 10 by the control device 4, the high-pressure fuel pumped from the fuel tank to the common rail device 41 by the fuel supply pump is discharged to each The injection pressure, injection timing, and injection period (injection amount) of the fuel injected from the injector into each cylinder of the engine 10 and supplied from each injector are controlled with high precision.

The transmission 42 is specifically, for example, a movable swash plate type hydraulically operated continuously variable transmission, and is provided in the transmission case 22 . By controlling the transmission device 42 with the control device 4 and adjusting the angle of the swash plate appropriately, the transmission gear ratio of the transmission case 22 can be set to a desired transmission ratio.

The elevating actuator 44 moves the work machine 3 to a retracted position (a position where agricultural work is not performed) or a working position by operating a three-point link mechanism connecting the work machine 3 to the body 2, for example. It is to raise and lower it to one of the (locations where agricultural work is performed). By controlling the elevating actuator 44 with the control device 4 and raising and lowering the work machine 3 appropriately, for example, agricultural work can be performed with the work machine 3 at a desired height in the field area.

In addition, the control device 4 includes a rotational speed sensor 31 that detects the rotational speed of the engine 10, a vehicle speed sensor 32 that detects the rotational speed of the rear wheels 8, and a rotation angle of the steering wheel 12 ( Sensors such as a steering angle sensor 33 that detects a steering angle) are also electrically connected. The detection values of these sensors are converted into detection signals and transmitted to the control device 4 .

In the tractor 1 provided with the control device 4 as described above, when an operator gets inside the cabin 11 and performs various operations, the control device 4 controls each part of the tractor 1 (aircraft body). (2), the work machine 3, etc.) are controlled so that agricultural work can be performed while traveling in the field. In addition, the tractor 1 of the embodiment can be autonomously driven based on a predetermined control signal output by the remote control device 46, for example, even without an operator riding on the tractor.

Specifically, as shown in FIG. 3 , the tractor 1 includes various components in the controller 4 for enabling autonomous driving. In addition, the tractor 1 is provided with various configurations such as an antenna 6 for positioning necessary to acquire positional information of (the aircraft) by itself based on the positioning system. With such a configuration, the tractor 1 can acquire its own positional information based on the positioning system and autonomously travel on the pavement.

Next, the structure provided to the tractor 1 for autonomous driving will be described in detail. Specifically, as shown in FIGS. 1 and 3 , the tractor 1 includes a steering actuator 43, an antenna 6 for positioning, an antenna 48 for radio communication, and the like.

The steering actuator 43 is formed, for example, at a midway portion of the rotational axis (steering shaft) of the steering handle 12, and adjusts the rotation angle (steering angle) of the steering handle 12. When the tractor 1 travels (as an unmanned tractor) on a predetermined path, the controller 4 calculates an appropriate angle of rotation of the steering handle 12 so that the tractor 1 travels along the path, The steering actuator 43 is controlled so that the steering wheel 12 rotates at the calculated angle of rotation.

The positioning antenna 6 receives signals from positioning satellites constituting a positioning system such as a satellite positioning system (GNSS), for example. As shown in FIG. 1 , the positioning antenna 6 is disposed on the upper surface of the lid 14 in the cabin 11 . The signal received by the positioning antenna 6 is input to the position and inclination information calculation unit 49 shown in FIG. Positional information of the positioning antenna 6 is calculated as latitude/longitude information, for example. The position information calculated by the position and inclination information calculation unit 49 is acquired by the position and inclination information acquisition unit 50 of the control device 4 and used for controlling the tractor 1 .

The position and inclination angle information calculation unit 49 of the embodiment is capable of measuring not only the positional information of the tractor 1 (body 2) but also the inclination angle information of the front, rear, left and right directions. The inclination angle information measured by the position and inclination angle information calculation unit 49 is acquired in a state of being associated with positional information (latitude/longitude information) by the position and inclination information acquisition unit 50 of the control device 4, and the tractor It is used for control of (1). In addition, the position and inclination angle information calculation unit 49 can measure the height position of the positioning antenna 6 with respect to the pavement surface and, consequently, the vehicle height of the tractor 1 (body 2).

Further, in the present embodiment, a high-precision satellite positioning system using the GNSS-RTK method is used, but it is not limited to this, and other positioning systems may be used as long as high-precision position coordinates are obtained. GNSS-RTK is a positioning method in which accuracy is improved by correcting based on information of a reference station whose position is known, and there are a plurality of methods due to differences in the method of distributing information from the reference station. Since the present invention does not depend on the GNSS-RTK scheme, details are omitted in this embodiment.

The antenna 48 for radio communication receives a signal from the remote control device 46 or transmits a signal to the remote control device 46. As shown in FIG. 1 , the antenna 48 for radio communication is disposed on the upper surface of the lid 14 of the cabin 11 of the tractor 1 . The signal from the remote control device 46 received by the antenna 48 for radio communication is signal-processed by the transmission/reception processing unit 47 shown in FIG. 3 and then input to the control device 4. Further, the signal to be transmitted from the control device 4 to the remote control device 46 is signal-processed by the transmission/reception processing unit 47, transmitted from the antenna 48 for radio communication, and transmitted by the remote control device 46. Received.

In addition, in the tractor 1, a pair of left and right brake devices 26, 26 for applying brakes to the left and right rear wheels 8, 8 are formed by two systems: operation of the brake pedal or parking brake lever and automatic control. are doing That is, the left and right brake devices 26 and 26 are configured to brake the left and right rear wheels 8 and 8 by operating the brake pedal (or parking brake lever) in the braking direction. In addition, when the rotation angle of the handle 12 exceeds a predetermined angle, the brake device 26 for the rear wheel 8 on the inside of the swing automatically performs a braking operation in response to a command from the control device 4. (so-called auto brake).

In addition, the tractor 1 is equipped with an obstacle sensor 35 that detects whether or not there is an obstacle in the front, side or rear. The obstacle sensor 35 is constituted by a laser sensor, an ultrasonic sensor, or the like, and recognizes obstacles present in front, side, and rear of the tractor 1, and generates a detection signal. In addition, the tractor 1 is equipped with a camera 36 that takes pictures of the front, side and rear. Obstacle sensor 35 and camera 36 are electrically connected to control device 4 . The detection values of these sensors are converted into detection signals and transmitted to the control device 4 .

The remote control device 46 is specifically constituted by a tablet type personal computer equipped with a touch panel. The operator can check with reference to information displayed on the touch panel of the remote control device 46 (for example, pavement information necessary for autonomous driving). In addition, the operator can operate the remote control device 46 to transmit a control signal for controlling the tractor 1 to the control device 4 of the tractor 1. Further, the remote control device 46 of the embodiment is not limited to a tablet-type personal computer, and may be configured as, for example, a notebook-type personal computer instead. Alternatively, when a manned tractor (not shown) is driven along with the unmanned tractor 1, the monitor device mounted on the manned tractor can be used as a remote control device.

The control device 4 shown in FIG. 3 is provided with each part for autonomous driving control of the tractor 1, and by forming various components such as a positioning antenna 6 and the like in the tractor 1, the conventional A tractor can be used as an unmanned tractor (1). The control device 4 is constituted by a small computer having a CPU, ROM, RAM, and the like, and operation programs, application programs, various data, and the like are stored in the ROM. By cooperation of the above hardware and software, the control device 4 is configured with a position and inclination information acquisition unit 50, an area information storage unit 51, a job information storage unit 52, an outline registration point storage unit 53, It can be operated as the region shape acquisition unit 54, path generation unit 55, display data creation unit 56, and the like.

The tractor 1 configured as described above calculates a travel path in the pavement area (travel area) by the path creation unit 55 according to the operator's instruction using the remote control device 46, and calculates the travel path. It is possible to perform agricultural work by the implement 3 while autonomously traveling along the road. In this way, a path within a pavement area (travel area) on which the tractor 1 autonomously travels may be referred to as a "travel path" in the following description. In addition, in a pavement area (running area), an area to be subjected to agricultural work by the work machine 3 of the tractor 1 may be referred to as a "work area". The work area is determined as an area excluding the open space and margins from the entire pavement area, and when an operator or the like executes a registration work for registration points described later, these registration points and the work width of the tractor 1 are set. do.

Next, each part provided in the control device 4 to enable autonomous driving will be individually described with reference to FIG. 3 .

The position and inclination information acquisition unit 50 constituted using the control device 4 transmits information to the position and inclination information calculation unit 49 based on the positioning signal from the positioning system acquired by the positioning antenna 6. In addition to acquiring position information (specifically, latitude/longitude information, etc.) of the tractor 1 calculated by It is obtained in a state of being associated with positional information (latitude/longitude information).

An area information storage unit 51 configured using the control device 4 stores various types of information related to areas such as farm fields to which autonomous driving agricultural work is performed on the tractor 1 . As the information on the pavement, specifically, the position and shape of the pavement (which may be a pavement area or a driving area), the position and shape of a work area in which agricultural work is performed by the work machine 3 in the pavement, and the work machine in the pavement ( 3) The start position, which is the point at which agricultural work is started, and the end position, which is the point where agricultural work is finished.

The position and shape of the pavement, that is, the pavement area (travel area), prior to generating the travel route, is determined from the travel trajectory when the body 2 of the tractor 1 is manned and driven around the pavement, , is acquired by a region shape acquisition unit 54 described later. The step before generating the traveling route corresponds to the step before starting the travel of the tractor 1 (substrate 2) accompanying agricultural work with the work machine 3. In addition, the position and shape of the work area are also acquired by a region shape acquisition unit 54 described later. Other information can be set, for example, by an operator operating the touch panel of the remote control device 46 or the like. The information of the start position and the end position is set by an operator operating the touch panel of the remote control device 46 after obtaining the information of the pavement area (running area) by the area shape acquiring unit 54 . The information on the pavement area or work area (which may also be referred to as area information) includes left and right inclination angle information associated with each positional information (latitude/longitude information).

The work information storage unit 52 configured using the control device 4 stores the type of work to be executed by the work implement 3 mounted on the body 2 of the tractor 1, the work width, the overlap width, and the like, It is memorized as work information. In the embodiment, these information can be set by an operator operating the touch panel of the remote control device 46 . As the type of work, for example, plowing work, sowing work, and the like. The work width means an effective width in which work is performed by the work machine 3, and is 3 meters, for example. The overlap width means the width at which the working widths of the implements 3 overlap (overlapping is permitted) when the tractors 1 travel on travel paths adjacent to each other, for example, 30 cm. am.

The contour registration point storage unit 53 configured using the controller 4 stores a plurality of points constituting the contour of the pavement area F (running area) shown in FIG. 4 (for example, the corner portion F1 to F4)), when the operator performs the operation of registering the position information when the body 2 of the tractor 1 is located, the position information and the inclination angle information corresponding thereto are stored. As described above, the identification of the pavement area F is obtained based on the travel trajectory when the body 2 of the tractor 1 is driven and travels around the pavement prior to generating the travel route. In the embodiment, the contour registration point storage unit 53 stores positional information and inclination angle information at the plurality of points on the travel trajectory. In this embodiment, a point registered in the contour registration point storage unit 53 is sometimes referred to as a registration point.

The area shape acquisition unit 54 acquires the shape (including the inclination) of the pavement area F based on the positional information and inclination angle information of a plurality of registration points read from the contour registration point storage unit 53. In addition, the area shape acquisition unit 54 obtains the shape of the work area W based on the above-described shape of the pavement area F and the job information (at least the work width information) read from the work information storage unit 52. Get the shape (including the slope). Specifically, a polygon (in the embodiment, a quadrangle) specified by a so-called closed graph is obtained as the shape of the pavement area F or work area W so that the line segments connecting the registration points do not intersect.

The path creation unit 55 determines the body 2 of the tractor 1 based on the job information read from the job information storage unit 52 and the work area W information read from the area information storage unit 51. ) is created by calculation. The traveling route P includes a plurality of straight roads Ps and a plurality of turning circuits Pc. That is, the travel route P includes a straight road Ps (which may be referred to as a work route), which is a straight or broken route on which agricultural work is performed, and a turning circuit (Pc on which a turning operation (direction change) is performed ) (which can also be referred to as non-working routes) are created as a series of paths alternately connected. Therefore, according to the embodiment, the area of the pavement area F can be measured with high accuracy by specifying the pavement area F after considering the inclination. As a result, it is possible to generate an optimal travel path P.

The display data creation unit 56 acquires the shapes of the pavement area F and the work area W acquired by the area shape acquisition unit 54 and stored in the area information storage unit 51, and the remote control device 46 ) Create display data for display on the touch panel. The display data created by the display data creation unit 56 is received by the remote control unit 46 via the transmission/reception unit 47, and is displayed as an image on the touch panel of the remote control unit 46. .

Next, modes of autonomous travel start reservation control and autonomous travel stop reservation control of the tractor 1 will be described with reference to FIGS. 5 to 12 . Here, a robot tractor 1 capable of autonomous traveling unmanned is accompanied by a tractor 101 (hereinafter sometimes referred to as a "manned tractor") which an operator rides and controls, and both tractors 1, 101 ), that is, a case in which the same type of implements 3 and 103 are attached to each of the unmanned tractor 1 and the manned tractor 101 to perform agricultural work while paralleling will be described as an example. .

The manned tractor 101 as another work vehicle is boarded and operated by an operator, and is capable of operating the unmanned tractor 1 by mounting the above-described remote operation device 46. Since the basic configuration of the manned tractor 101 is almost the same as that of the unmanned tractor 1, a detailed description thereof will be omitted. In addition, the code of each part of the manned tractor 101 is set to a number obtained by adding “100” to the code of each part of the unmanned tractor 1 corresponding thereto (for example, the body 2 of the unmanned tractor 1) Against the airframe 102 of the manned tractor 101). As shown in FIG. 9 , the unmanned tractor 1 travels along the travel path P, and the manned tractor 101 travels backward (may be sideways) inclined to the left or right, and the manned tractor 101 ), it is possible to perform agricultural work in the field while monitoring the unmanned tractor 1.

The remote control device 46 is detachable from an operating unit such as a dashboard in the manned tractor 101 or the unmanned tractor 1. Therefore, the remote control device 46 is capable of operation in the state of being attached to the manipulator of the manned tractor 101, operation of carrying out of the pavement outside both tractors 1 and 101, and also of the manipulator of the unmanned tractor 1. It can also be operated while mounted. In the examples after FIG. 8 , it is assumed that the remote control device 46 is operated in a state attached to the manipulator 101 of the manipulator 101 .

Fig. 7 shows an example of a display screen of the remote control device 46 during autonomous driving of the unmanned tractor 1. On the touch panel of the remote control device 46, images of the pavement area F, the work area W, and the travel route P are displayed, as well as starting autonomous driving of the unmanned tractor 1 or stopping autonomous driving (temporarily). A start/stop switch 58 for operating the stop), an emergency stop switch 59 for emergency stopping the unmanned tractor 1, and the like are displayed. The difference between temporary stop and emergency stop of the tractor (1) is that, when the tractor (1) is temporarily stopped, autonomous driving of the tractor (1) is achieved by pressing down the start/stop switch (58) of the remote control device (46). compared to being able to start the autonomous driving of the tractor 1 by pressing down the start/stop switch 58 of the remote control device 46 when the tractor 1 is emergency stopped. is in When the tractor 1 is stopped in an emergency, the operator gets on the tractor 1 and performs an initialization operation (for example, turning the PTO switch "OFF" once for a predetermined function (eg, ON/OFF of the PTO switch). and then turn it to “ON”) to start autonomous driving.

When the start/stop switch 58 is briefly pressed with a finger or a pen in a state where the unmanned tractor 1 stops driving, the unmanned tractor 1 immediately starts autonomous driving. When the start/stop switch 58 is briefly pressed with a finger or a pen during autonomous driving of the unmanned tractor 1, the unmanned tractor 1 immediately stops autonomous driving.

In addition, if the start/stop switch 58 is pressed for a long time with a finger or a pen (for example, about several seconds) in a state where the unmanned tractor 1 is stopped driving, autonomous driving start reservation control of the unmanned tractor 1 is executed. (Details are described later). If the start/stop switch 58 is pressed for a long time with a finger or a pen (for example, about several seconds) during autonomous driving of the unmanned tractor 1, the autonomous driving stop reservation control of the unmanned tractor 1 is executed (see details). described below).

As described above, the remote control device 46 and the unmanned tractor 1 can communicate with each other wirelessly. In addition to this, the unmanned tractor 1 and the manned tractor 101 can also communicate with each other wirelessly. A signal to be transmitted from the control device 104 of the manned tractor 101 to the unmanned tractor 1 is signal-processed by the transmission/reception processing unit 147, and then transmitted from the antenna 148 for radio communication, and the unmanned tractor 1 is received by the antenna 48 for radio communication. The signal from the manned tractor 101 received by the antenna 48 for radio communication is signal-processed by the transmission/reception processing unit 47, and then input to the control device 4 of the unmanned tractor 1. Therefore, the control device 4 of the unmanned tractor 1 outputs the position information (latitude/longitude information) of the manned tractor 101 received by the positioning antenna 106 and calculated by the position and inclination angle information calculation unit 149. ) can be obtained.

The control device 4 of the unmanned tractor 1 controls the unmanned tractor 1 (subframe 2) until a travel start condition is established in starting autonomous travel of the unmanned tractor 1 (subframe 2). )) can be queued. For example, the unmanned tractor 1 is stopped at the starting position S in the pavement, and the unmanned tractor 1 is tilted to the left or right at the backward (sideward) position A (see Fig. 9). When the operator presses and holds the start/stop switch 58 of the remote control device 46 with a finger or a pen while or immediately before the operator controls the manned tractor 101, the operation of the unmanned tractor 1 Autonomous driving start reservation control is started.

8 is a flowchart showing an example of autonomous driving start reservation control. In this case, when a predetermined time (for example, about 10 seconds) elapses after pressing and holding the start/stop switch 58 is finished (S101: Yes), the condition for completing the preparation of the unmanned tractor 1 is established (S102 : Yes), the unmanned tractor 1 is stopped at a predetermined position (start position (S) in this case) (S103: Yes), and there is no abnormality in each part of the unmanned tractor 1 (S104: Yes), The autonomous driving of the unmanned tractor 1 along the traveling route P is started (S105). If any part of the unmanned tractor 1 has a problem (S104: No), the unmanned tractor 1 maintains a stopped state (S106). Since a predetermined time (for example, about 10 seconds) is required before the autonomous driving of the unmanned tractor 1 starts, the manned tractor 101 operated by the operator until then reaches the accompanying position A (or It is possible to wait at the accompanying position (A)). Therefore, agricultural work can be smoothly started while cooperating with the unmanned tractor 1 and the manned tractor 101.

Whether or not a predetermined time (for example, about 10 seconds) elapses after pressing and holding the start/stop switch 58 shown in step S101 of FIG. Elapse of the predetermined time after pressing and holding the start/stop switch 58 is completed constitutes the establishment of the traveling start condition. As preparation completion conditions, the unmanned tractor 1 is positioned (does not deviate) on the travel path P, and the positioning antennas 6 and 106 can receive signals from positioning satellites (not cut off). state), and communication between the unmanned tractor 1 and the remote control device 46 is not disconnected. As an abnormality of each part of the unmanned tractor 1, abnormality of various sensors, actuators, etc. is mentioned, for example.

Control as described above makes it possible to reserve the start of autonomous driving of the unmanned tractor 1, and after carrying out an operation to start autonomous driving of the unmanned tractor 1 in advance, a desirable time point at which the conditions for starting the driving are met (e.g., unmanned When the tractor 1 and the manned tractor 101 are paralleled, autonomous driving of the unmanned tractor 1 can be started when the manned tractor 101 arrives at a lifting position, etc.). It is not necessary for the operator to perform an autonomous driving start operation at the time when autonomous driving of the unmanned tractor 1 is to be started, and the driving operability of the unmanned tractor 1 is improved.

10 is a flowchart showing another example of autonomous driving start reservation control. In the autonomous driving start reservation control of another example shown in FIG. 10, the driving start condition is that the current position of the manned tractor 101 transmitted from the manned tractor 101 to the unmanned tractor 1 is at least a predetermined position (of the unmanned tractor 1). It includes the following position (A) in the rear (which may be lateral) inclined to the left or right. In addition, the preparation completion condition of the said other example is the same as the preparation possibility condition of the previous example.

In this case, when the operator presses and holds the start/stop switch 58 of the remote control device 46 with a finger or a pen to start the autonomous driving start reservation control of the unmanned tractor 1, the preparation of the unmanned tractor 1 is completed. The condition is established (S201: YES), the unmanned tractor 1 is stopped at a predetermined position (start position (S) in this case) (S202: YES), and the manned tractor 101 is at a predetermined position (accompanying in this case). When the position (A) is reached (S203: Yes) and there is no abnormality in each part of the unmanned tractor 1 (S204: Yes), autonomous driving of the unmanned tractor 1 along the travel route P is started. (S205). If any part of the unmanned tractor 1 has a problem (S204: No), the unmanned tractor 1 maintains a stopped state (S206).

Therefore, even when controlled as in the other example, the same operation and effect as in the previous example is exhibited, but on the condition that the manned tractor 101 operated by the operator reaches the accompanying position A, the unmanned tractor 1 Since the autonomous driving is started, the timing of starting the autonomous driving of the unmanned tractor 1 can be adjusted with higher precision than in the previous example in which the unmanned tractor 1 is waited for a predetermined time.

On the other hand, the control device 4 of the unmanned tractor 1 stops the autonomous driving of the unmanned tractor 1 (body 2) until the driving stop condition is satisfied. (2)) can continue to run. For example, during the parallel operation of the unmanned tractor 1 and the manned tractor 101, when the operator presses and holds the start/stop switch 58 of the remote control device 46 with a finger or a pen, the autonomous tractor 1 Travel stop reservation control is started.

11 is a flowchart showing an example of autonomous driving suspension reservation control. When the autonomous driving stop reservation control of the unmanned tractor 1 is started, the preparation completion condition of the unmanned tractor 1 is established (S301: YES) and if there is no abnormality in each part of the unmanned tractor 1 (S302: YES) ), the self-driving of the unmanned tractor 1 is continued until the expected stop position (ST) (the position connected to the next turning circuit (Pc)), which is the end of the straight road (Ps) currently being autonomously driven (S303). When the unmanned tractor 1 reaches the expected stop position (S304: YES), the autonomous driving of the unmanned tractor 1 is stopped (S305). If there is an abnormality in any part of the unmanned tractor 1 (S302: No), the process proceeds to step S305, and the unmanned tractor 1 immediately stops autonomous driving.

In the driving stop condition of the example shown in FIG. 11, the unmanned tractor 1 based on the positional information (latitude/longitude information) received by the positioning antenna 6 and calculated by the position and inclination information calculator 49 (aircraft ( 2)) is a predetermined position (in this case, the expected stop position ST). In addition, the preparation completion condition in this example is the same as the preparation availability condition shown in the example of autonomous driving start control and other examples.

Control as described above makes it possible to reserve the autonomous driving stop of the unmanned tractor 1, and after performing the autonomous driving stop operation for the unmanned tractor 1 in advance, a desirable point in time at which the driving stop condition is satisfied (e.g., unmanned The autonomous driving of the unmanned tractor 1 can be stopped when the tractor 1 arrives at the opening of the field, etc.). It is not necessary for an operator to perform an autonomous driving stop operation in time to stop the autonomous driving of the unmanned tractor 1, and the driving operability of the unmanned tractor 1 is improved.

In the above embodiment, the control device 4 of the tractor 1 includes a position and inclination information acquisition unit 50, an area information storage unit 51, a work information storage unit 52, and an outline registration point storage unit ( 53), the region shape acquisition unit 54, the route generation unit 55, and the display data creation unit 56, but are not limited thereto. That is, the above configuration may be provided in the remote control device 46, and a part of the configuration may be provided in the control device 4, and may be provided in the remote control device 46 as another part. In addition, both the control device 4 and the remote control device 46 may be equipped with all or part of the above structure.

Therefore, the path creation device of the present invention may be configured to be provided to the tractor 1 or may be configured to be provided to the remote control device 46 . When the path creation device is provided in the remote control device 46, the remote control device 46 obtains the location information of the tractor 1 calculated by the position and inclination information acquisition unit 50 provided in the tractor 1. and inclination angle information can be obtained through the antenna 48 for radio communication. Further, when a travel route is generated by the remote control device 46, the remote control device 46 is provided with storage units 51 and 52, and the information acquired from the storage units 51 and 52 (work information and the information of the work area (W)). Then, the remote control device 46 can instruct the tractor 1 to travel along the generated travel route (transmitting an autonomous driving start control signal), and in that case, the control device 4 can control the remote control device ( 46) to control each part of the tractor 1 according to the instructions of 46) to drive autonomously.

Next, the mode of travel route correction control in the embodiment will be described with reference to FIGS. 13 to 16 . As described above, the controller 4 (path generating unit 55) determines the starting position S at which the aircraft 2 starts traveling and the ending position E at which the traveling of the aircraft 2 ends. Not only can the travel route P be generated, but also accept a position change of either the start position S or the end position E after the travel route P is created, and the travel route P after creation can be changed. is editable.

In addition, in the following description and drawings, for convenience, the original work area (W), the original travel route (P), the original start position (S), and the original end position (E) are marked with the letter “o”. There are cases. In some cases, the new work area (W), the new travel route (P), the new start position (S), and the new end position (E) are marked with the letter "n".

When accepting a position change, the control device 4 (route creation unit 55) sets a predetermined position within the pavement area F and outside the original travel path Po as a new starting position Sn or a new one. It is also possible to accept as the end position En, and it is also possible to accept a predetermined position on the original travel route Po as a new start position Sn or a new end position En.

In the modified example shown in FIGS. 13(a) to (d) and 14(e) to (h), a predetermined position within the pavement area F and outside the original travel route Po is set as a new starting position Sn. Alternatively, this is an example of a case where a new end position En is used, and the modified examples shown in FIGS. 15(i) to (l) and 16(m) to (p) change a predetermined position on the original travel route Po This is an example of a new start position (Sn) or a new end position (En). In either example, the starting position S is positioned on the boundary periphery wa where the original starting position So was located or on an extension of the boundary periphery wa of the boundary periphery wa to wd of the work area W. It is possible to change. Further, the end position E can be positioned on the boundary periphery wa where the original end position Eo was or on the extension of the boundary periphery wa.

In any modification, the new start position Sn (or the new end position En) is the boundary periphery (wb, wd) cannot be set so far from the original start position So (or the original end position Eo) that it protrudes from the pavement area F. In the modified examples shown in FIGS. 13, 14, 15(i) (j) and 16(m) (n), the settable range of the new start position Sn (or new end position En) is , within a range equal to the distance D between adjacent straight roads Ps on both sides of the original start position So (or the original end position Eo) therebetween. In other words, the distance from the boundary periphery wb before correction to the end of the paved area F is set to a distance longer than the distance D between adjacent straight roads Ps, and the original starting position So Even if the new start position Sn is corrected, it is set so that the body 2 and the work machine 3 are not pushed out of the area of the pavement area F.

In the modified examples shown in FIGS. 13(a) to (d) and 15(i)(j), before the autonomous driving of the tractor 1 (substrate 2), the pavement area F and the original work area ( Wo) and the original travel route Po are displayed on the touch panel of the remote control unit 46, and when the vicinity of the original starting position So is pressed with a finger or a pen on the touch panel, the remote control unit 46 ) on the touch panel, the display of the starting position (S) is completely replaced from the original starting position (So) to the new starting position (Sn) corresponding to the pressing position (FIG. 13(a) (c) and FIG. 15(i)). Then, on the touch panel of the remote control device 46, the work area W within the pavement area F and the end position E correspond to the positional deviation of the new starting position Sn (distance between So and Sn). ) and travel path P are modified by being switched from the original ones Wo, Eo, Po to the new ones Wn, En, Pn (Fig. 13(b) (d) and Fig. 15(j)) reference).

Similarly, in the modified examples shown in FIGS. 14(e) to (h) and 16(m) (n), when the vicinity of the original end position En is pressed with a finger or a pen on the touch panel, the remote control device ( 46), the display of the end position (E) is switched from the original end position (Eo) to the new end position (En) corresponding to the pressed position (FIG. 14(e)(g) and FIG. 16(m)). And, on the touch panel of the remote control device 46, the work area W in the pavement area F, the end position E, and the travel route P corresponding to the positional deviation of the new end position En. is modified by switching from the original Wo, Eo, Po to the new Wn, En, Pn state (see FIGS. 14(f) (h) and 16(n)).

In any of the above cases, the original work area W (= Wo), the start position (S) (= So), and the end position (E) ( = Eo) and travel route P (= Po) information are replaced with new Wn, Sn, En, and Pn.

In the modified example shown in FIGS. 15(k)(l) and 16(o)(p), the first (or last) round trip in the original travel route Po is skipped, and the first (last) round trip is skipped. counting from , and the end position of the third straight path Ps is set as the new start position Sn (or new end position En). In this case, on the touch panel of the remote control device 46, one first (or last) round trip in the original travel route Po is deleted, but the original end position Eo (or the original start position) is deleted. (So)) remains as it is, and the working area (W) and travel route (P) in the pavement area (F) are converted from the original ones Wo, Po to the new ones Wn, Pn in a modified state.

In the modified example shown in FIG. 15(k)(l), the original work area W (= Wo) stored in the control device 4 (area information storage unit 51), the starting position S (= So) and travel route P (= Po) are replaced with new ones Wn, Sn, and Pn. The information of the end position (E) (= Eo) is maintained. In the modified example shown in Fig. 16(o) (p), the original work area W (= Wo) stored in the control device 4 (area information storage unit 51), the end position (E) (= Eo) and travel route P (= Po) are replaced with new ones Wn, En, and Pn. The information of the starting position (S) (= So) is maintained.

If the above control is performed, for example, even when there is a deep groove near the starting position S of the pavement and there is a risk of impeding autonomous driving of the tractor 1 (body 2), the previously created travel route It is possible to divert and correct the previously generated travel route P only by changing the position of either one of the starting position S and the ending position E without recreating the P itself from scratch. Accordingly, the setting workability of the travel route P can be improved, the operator's workload is reduced, and the travel route P adapted to the pavement conditions can be generated.

In the above embodiment, the control device 4 of the tractor 1 includes a position and inclination information acquisition unit 50, an area information storage unit 51, a work information storage unit 52, and an outline registration point storage unit ( 53), the region shape acquisition unit 54, the route generation unit 55, and the display data creation unit 56, but are not limited thereto. In other words, the remote control device 46 may have the above configuration, and a part may be provided in the control device 4 and the remote control device 46 may be provided with the other part. In addition, both the control device 4 and the remote control device 46 may be equipped with all or part of the above structure.

Therefore, the path creation device of the present invention may be configured to be provided to the tractor 1 or may be configured to be provided to the remote control device 46 . When the path creation device is provided in the remote control device 46, the remote control device 46 obtains the location information of the tractor 1 calculated by the position and inclination information acquisition unit 50 provided in the tractor 1. and inclination angle information can be obtained through the antenna 48 for radio communication. Further, when a travel route is generated by the remote control device 46, the remote control device 46 is provided with storage units 51 and 52, and the information acquired from the storage units 51 and 52 (work information and the information of the work area (W)). Then, the remote control device 46 can instruct the tractor 1 to travel along the generated travel route (transmitting an autonomous driving start control signal), and in that case, the control device 4 can control the remote control device ( 46) to control each part of the tractor 1 according to the instructions of 46) to drive autonomously.

As described above, the driving route P is a route generated based on the starting position S and the ending position E, and the starting position S and the ending position E are based on driving area information. After acquisition by the region shape acquisition unit 54, it is set by the operator and stored in the region information storage unit 51. In modifying the original travel route Po to the new travel route Pn, changes in the start position S (original start position So) and end position E (original end position Eo) In the present embodiment, when the start position (S) and the end position (E) are changed, the start position after the change (ie, the new start position (Sn)) and the end position after the change (ie, the new end position (En) )) is stored in the area information storage unit 51, but it is not limited thereto. That is, in the area information storage unit 51, the original work area Wo, the original start position So, the original end position Eo, and the original travel route Po are stored, and each piece of information is stored. It is also possible to add and store correction information indicating that . As a result of this process, for example, when a plurality of travel routes are generated based on the original start position (So), even if the start position (S) is corrected in one travel route, the start of another travel route The position S is not modified, and a modification of one travel route can be prevented from affecting another travel route.

Next, the mode of travel path division control in the embodiment will be described with reference to FIG. 17 . The control device 4 of the embodiment can also operate as the unit path setting unit 57 (see Fig. 3) by cooperation of the hardware and software described above. The unit path setting unit 57 configured using the controller 4 sets a part of the travel path P as a unit path U for one trip of the tractor 1 (subframe 2). It is for That is, in the embodiment, after the travel path P is generated, the travel path P is divided into a plurality of unit paths U by the control device 4 (unit path setting unit 57) (separated and divided). ) is possible. Information on each divided unit path U and the like is newly stored in the control device 4 as the area information storage unit 51. When a group of unit routes (U) is set, autonomous travel of the tractor 1 (subframe 2) is controlled for each unit route (U) by the controller 4.

In addition, in FIG. 17 and the explanation thereof, for convenience, the original travel route P, the original start position S, and the original end position E may be indicated by appending the letter “o”. Further, in some cases, the starting position (S) and ending position (E) of each unit path (U) and each unit path (U) are indicated with numbers.

In the division example shown in FIG. 17(a) (b), after generating the travel path P (= Po) and before autonomous travel with the tractor 1 (subframe 2), for example, the remote control device ( 46) Press a route division button (not shown) displayed on the touch panel. Then, the pavement area F, work area W, and original travel route Po are displayed on the touch panel of the remote control device 46 . In this state, when the end position of any straight road Ps included on the original travel route Po is pressed with a finger or a pen, the end position E1 of the first unit route U1 corresponds to the pressed position. (which may be the first end position) is newly created (see Fig. 17(a)). In this case, the first unit path U1 is set from the original start position So to the first end position E1.

Then, at the end position of the straight path Ps connected to the first end position E1 via the turning circuit Pc, the start position S2 of the second unit path U2 (even if it is the second start position) is) is newly created (see FIG. 17(b)). In this case, the second unit path U2 is set from the second starting position S2 to the original ending position Eo. The turning circuit Pc between the first ending position E1 and the second starting position S2 is deleted. As a result, the original travel route Po is divided (divided by division) into two, the first unit route U1 and the second unit route U2. Therefore, for example, even in the case of carrying out agricultural work over multiple days in a large-scale field, it is useful without recreating the previously generated driving route Po itself from scratch, and a plurality of unit routes U can be set Therefore, for example, the working range (running range) in the field can be easily partitioned and divided in consideration of the working time and the like, and the operator's workload is reduced. In addition, it becomes easy to organize the work process of a day, for example. A first unit path U1, a first end position E1, a second unit path U2, and a second start position S2 are newly stored in the control device 4 (area information storage unit 51). do.

The control device 4 (unit path setting unit 57) of the embodiment sets the intermediate position of any straight road Ps included in the original travel path Po to the starting position of each unit path U. (S) and end position (E) are prohibited. Therefore, the tractor (1) (subject (2)) autonomously traveling on each unit path (U) is free from the center (corresponding to the midway position of each straight road (Ps)) away from the middle of the pavement, for example. There is no fear of stopping running or starting running.

In addition, the original travel path Po is not limited to two, and it is also possible to divide into three or more unit paths U. In this case, the aforementioned unit path setting operation (path division setting operation) may be performed a plurality of times. Further, during autonomous travel of the tractor 1 (substrate 2), the above-described unit route setting operation (path division setting operation) can be executed by pressing a route division button (not shown) on the touch panel. In this case, it is permitted to set only on a path on which the tractor 1 (subframe 2) does not travel among the original travel paths Po. This is because it is not necessary to execute the above-mentioned unit path generation job (path division job) on the already traveled route.

In the present embodiment, the travel route is divided after the travel route P is generated and before the tractor 1 (subframe 2) autonomously travels, but before the travel route P is created, the work area ( W) may be divided and travel routes may be generated in each work area. In that case, before generating the travel route P, for example, a region division button (not shown) displayed on the touch panel of the remote control device 46 is pressed. Then, the pavement area F, work area W, and the like are displayed on the touch panel of the remote control device 46 . In this state, when an arbitrary position (or any position among a plurality of positions marked to be selectable) is pressed with a finger or a pen, the work area W is divided in correspondence with the pressed position. The number of divisions of the work area W can also be appropriately set. For example, when the work area W is divided into two parts, the work area W1 and the work area W2, the width of each area W1 and W2 and, based on the work width, a new end position En in the work area W1 and a new start position Sn in the work area W2 are appropriately set. In the work area (W1), a travel route from the original start position (So) to the new end position (En) is created, and in the work area (W2), from the new start position (Sn) to the original end position (Eo). ) is created.

In the above embodiment, the control device 4 of the tractor 1 includes a position and inclination information acquisition unit 50, an area information storage unit 51, a work information storage unit 52, and an outline registration point storage unit ( 53), region shape acquisition unit 54, path generation unit 55, display data creation unit 56, and unit path setting unit 57, but are not limited thereto. In other words, the remote control device 46 may have the above configuration, and a part may be provided in the control device 4 and the remote control device 46 may be provided with the other part. In addition, both the control device 4 and the remote control device 46 may be equipped with all or part of the above structure.

Therefore, the path creation device of the present invention may be configured to be provided to the tractor 1 or may be configured to be provided to the remote control device 46 . When the path creation device is provided in the remote control device 46, the remote control device 46 obtains the location information of the tractor 1 calculated by the position and inclination information acquisition unit 50 provided in the tractor 1. and inclination angle information can be obtained through the antenna 48 for radio communication. Further, when a travel route is generated by the remote control device 46, the remote control device 46 is provided with storage units 51 and 52, and the information acquired from the storage units 51 and 52 (work information and the information of the work area (W)). Then, the remote control device 46 can instruct the tractor 1 to travel along the generated travel route (transmitting an autonomous driving start control signal), and in that case, the control device 4 can control the remote control device ( 46) to control each part of the tractor 1 according to the instructions of 46) to drive autonomously.

The present invention is not limited to the above-described embodiment, and can be embodied in various aspects. The configuration of each part is not limited to the illustrated embodiment, and various changes are possible without departing from the spirit of the present invention.

1: Robot Tractor
2: gas
3 : working machine
4: control device
6: positioning antenna
26: brake device
46: remote control device
48: antenna for wireless communication
49: position and inclination information calculation unit
50: location and inclination information acquisition unit
51: area information storage unit
52: work information storage unit
53: contour registration point storage unit
54: region shape acquisition unit
55: path generation unit
56: data creation unit for display
58: start/stop switch

Claims (4)

a path creation unit capable of specifying a driving area in which the agricultural work vehicle autonomously travels and generating in advance a travel path of the agricultural work vehicle in the driving area;
A control unit capable of instructing driving of the agricultural work vehicle along the driving route,
The route generating unit may generate the driving route based on a start position at which the agricultural work vehicle starts farming and an end position at which the agricultural work vehicle ends the farming work, and generation of the driving route Later, by accepting a position change of the start position or the end position, the start position may be changed to a new start position or the end position to a new end position;
By deleting a part of the created travel route and maintaining the remaining part of the created travel route as it is, in response to a change in the position of the starting position or the end position after the generation of the driving route, An autonomous driving system characterized in that the driving route can be modified. According to claim 1,
When the position change is accepted, the new starting position is a predetermined position within the driving area and outside the created driving route. According to claim 1 or 2,
An autonomous driving system, characterized in that the settable range of the new starting position relative to the starting position before the change is within a range of the same distance as a distance between adjacent work paths. According to claim 1 or 2,
The path generation unit generates the travel path by alternately connecting a plurality of work paths in which agricultural work is performed and a turning circuit in which a turning operation is performed,
The settable range of the new starting position with respect to the starting position before the change is the boundary periphery to which the starting position before the change belongs, or An autonomous driving system characterized in that it is an extension of the boundary periphery.

Images