JP7106418B2 - work vehicle - Google Patents

Description

The present invention relates to work vehicles such as tractors, for example.

Conventionally, patent document 1 is known as an agricultural working machine. The agricultural work machine of Patent Document 1 includes a traveling machine body capable of switching between manual traveling by manual steering and automatic traveling by automatic steering along a set traveling line set parallel to a reference traveling line, and manual traveling and automatic traveling. and a changeover switch that can freely switch between running and running. In addition, the starting point of the reference travel line is set after pressing the right instruction button while the agricultural implement is traveling along the ridge, and the end point of the reference travel line is set by pressing the left instruction button while traveling.

JP 2017-123803 A

The agricultural implement disclosed in Patent Literature 1 can easily travel automatically along a set travel line by switching from manual travel to automatic travel with a changeover switch. If the difference (positional deviation) between the agricultural implement and the set travel line is large, the steering angle becomes too large when the agricultural implement moves toward the set travel line, causing the agricultural implement to travel from its current position toward the set travel line. behavior may not be stable.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a work vehicle that can smoothly move (travel) from its current position to a planned travel line.

The technical means of the present invention for solving this technical problem are characterized by the following points.
The work vehicle includes a steering device that steers a vehicle body, a positioning device that detects the position of the vehicle body, a control device that controls automatic steering in the steering device so that a deviation between the vehicle body and a planned travel line is reduced, and the control device is arranged between the vehicle body position, which is the position of the vehicle body detected by the positioning device, and the planned travel line, at a position separated from the vehicle body position by a predetermined set distance. A target line setting unit that sets a parallel target travel line, and an automatic steering control unit that automatically steers the steering device so that the vehicle body heads toward the target travel line before the vehicle body reaches the planned travel line. and have The target line setting unit sets the target travel line when the deviation is equal to or greater than a predetermined value, and the automatic steering control unit controls the automatic steering of the vehicle body so as to approach the set target travel line. After setting the target travel line, the target line setting unit determines whether the deviation is equal to or greater than the predetermined value each time a predetermined condition is satisfied while the automatic steering control unit is executing the automatic steering. A determination is made, and if the deviation is equal to or greater than a predetermined value, the target travel line is reset to a position separated by the set distance from the vehicle body position at that time, and the automatic steering control unit controls the reset target travel line. The automatic steering of the vehicle body is performed so as to approach the running line.

The work vehicle includes a distance calculation unit that calculates a travel distance of the vehicle body, and the target line setting unit calculates the travel distance calculated by the distance calculation unit while the automatic steering control unit is performing the automatic steering. exceeds the threshold, it is determined that the predetermined condition is satisfied, and whether or not the deviation is equal to or greater than the predetermined value is determined in order to determine whether or not to reset the target travel line.

The target line setting unit assumes that the predetermined condition is satisfied and resets the target travel line each time the deviation decreases by a predetermined amount while the automatic steering control unit is performing the automatic steering . In order to determine whether or not, it is determined whether or not the deviation is equal to or greater than the predetermined value .
The work vehicle is provided with a timer that measures the elapsed time after the target travel line is set, and the target line setting unit is configured to operate the timer while the automatic steering control unit is executing the automatic steering. When the measured elapsed time exceeds a predetermined time, the predetermined condition is assumed to be satisfied, and whether the deviation is equal to or greater than the predetermined value for determining whether to reset the target travel line make a judgment as to whether

The target line setting unit ends the setting of the target travel line when the deviation is less than the predetermined value .
The work vehicle includes a steering handle for steering the vehicle body by manual steering, and a steering selector switch for switching between starting and ending the automatic steering.

According to the present invention, it is possible to smoothly move (travel) from the current position to the planned travel line.

It is a figure which shows the structure of a tractor, and a control block diagram. It is an explanatory view explaining automatic steering. It is an explanatory view explaining the amount of correction in a push switch. FIG. 5 is an explanatory diagram for explaining correction amounts in a slide switch; It is a figure which shows the 1st correction|amendment part and the 2nd correction|amendment part in a push switch. It is a figure which shows the 1st correction|amendment part and the 2nd correction|amendment part in a slide switch. The figure shows a state in which the calculated vehicle body position deviates to the right while the vehicle is traveling straight under automatic steering. This shows the state when the calculated vehicle body position deviates to the left while the vehicle is traveling straight under automatic steering. It is the figure which looked at the cover ahead of the driver's seat from the driver's seat side. It is an explanatory view explaining automatic steering. FIG. 10 is a diagram showing running trajectories of a tractor equipped with a target line setting unit and a tractor without a target line setting unit during automatic steering; FIG. 4 is a diagram showing a travel locus when resetting a target travel line based on travel distance; FIG. 10 is a processing flow diagram for resetting the target travel line based on the travel distance; FIG. 10 is a diagram showing a travel locus when the target travel line is reset based on the amount of change in positional deviation; FIG. 10 is a processing flow diagram for resetting the target travel line based on the amount of change in positional deviation; FIG. 10 is a diagram showing a travel locus when resetting a target travel line based on an elapsed time; FIG. 10 is a processing flow diagram for resetting the target travel line based on the elapsed time; 1 is an overall view of a tractor; FIG.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings.
12 is a side view showing one embodiment of the work vehicle 1, and FIG. 12 is a plan view showing one embodiment of the work vehicle 1. FIG. In this embodiment, work vehicle 1 is a tractor. However, the work vehicle 1 is not limited to a tractor, and may be an agricultural machine (agricultural vehicle) such as a combine harvester or a transplanter, or a construction machine (construction vehicle) such as a loader working machine.

Hereinafter, the front side of the driver seated in the driver's seat 10 of the tractor (work vehicle) 1 (direction of arrow A1 in FIG. 12) is the front side, the rear side of the driver (direction of arrow A2 in FIG. 12) is the rear side, and the left side of the driver. will be described as the left side and the driver's right side as the right side. Also, the horizontal direction, which is the direction orthogonal to the front-rear direction of the work vehicle 1, will be described as the width direction of the vehicle body.
As shown in FIG. 12 , the tractor 1 includes a vehicle body 3 , a prime mover 4 and a transmission 5 . The vehicle body 3 has a traveling device 7 and can travel. The traveling device 7 is a device having front wheels 7F and rear wheels 7R. The front wheels 7F may be of a tire type or a crawler type. Also, the rear wheel 7R may be of a tire type or a crawler type.

The prime mover 4 is a diesel engine, an electric motor, or the like, and is configured by a diesel engine in this embodiment. The transmission device 5 can switch the driving force of the traveling device 7 by changing speed, and can switch the traveling device 7 between forward and reverse. A driver's seat 10 is provided in the vehicle body 3 .
A connecting portion 8 configured by a three-point link mechanism or the like is provided at the rear portion of the vehicle body 3 . A working device can be attached to and detached from the connecting portion 8 . By connecting the working device to the connecting portion 8 , the working device can be towed by the vehicle body 3 . The work equipment includes a tillage device for tilling, a fertilizer spraying device for spraying fertilizer, an agricultural chemical spraying device for spraying agricultural chemicals, a harvesting device for harvesting, a reaper for cutting pasture, a spreading device for spreading pasture, and a sprayer for pasture. It is a grass collection device that collects grass such as grass, a forming device that forms pasture grass, and the like.

As shown in FIG. 1, the transmission 5 includes a main shaft (propulsion shaft) 5a, a main transmission portion 5b, an auxiliary transmission portion 5c, a shuttle portion 5d, a PTO power transmission portion 5e, a front transmission portion 5f, It has The propelling shaft 5a is rotatably supported by a housing case (mission case) of the transmission 5, and power from the crankshaft of the engine 4 is transmitted to the propelling shaft 5a. The main transmission portion 5b has a plurality of gears and a shifter for changing the connection of the gears. The main transmission section 5b changes the rotation input from the propulsion shaft 5a and outputs it (changes speed) by appropriately changing the connection (engagement) of a plurality of gears with a shifter.

The auxiliary transmission portion 5c has a plurality of gears and a shifter for changing the connection of the gears, like the main transmission portion 5b. The sub-transmission portion 5c appropriately changes the connection (engagement) of a plurality of gears with a shifter, thereby changing and outputting (shifting) the rotation input from the main transmission portion 5b.
The shuttle portion 5 d has a shuttle shaft 12 and a forward/reverse switching portion 13 . Power output from the auxiliary transmission portion 5c is transmitted to the shuttle shaft 12 via gears or the like. The forward/reverse switching unit 13 is composed of, for example, a hydraulic clutch or the like, and switches the rotation direction of the shuttle shaft 12, that is, the forward/reverse of the tractor 1, by turning on/off the hydraulic clutch. The shuttle shaft 12 is connected to the rear wheel differential device 20R. The rear wheel differential device 20R rotatably supports a rear axle 21R to which the rear wheels 7R are attached.

The PTO power transmission section 5 e has a PTO propulsion shaft 14 and a PTO clutch 15 . The PTO propulsion shaft 14 is rotatably supported and can transmit power from the propulsion shaft 5a. The PTO propulsion shaft 14 is connected to the PTO shaft 16 via a gear or the like. The PTO clutch 15 is composed of, for example, a hydraulic clutch or the like, and the power of the propelling shaft 5a is transmitted to the PTO propelling shaft 14 or not transmitted to the PTO propelling shaft 14 by turning on or off the hydraulic clutch. state.

The front transmission portion 5 f has a first clutch 17 and a second clutch 18 . The first clutch 17 and the second clutch 18 are capable of transmitting power from the propulsion shaft 5a, and for example, the power of the shuttle shaft 12 is transmitted via gears and transmission shafts. Power from the first clutch 17 and the second clutch 18 can be transmitted to the front axle 21</b>F via the front transmission shaft 22 . Specifically, the front transmission shaft 22 is connected to a front wheel differential device 20F, and the front wheel differential device 20F rotatably supports a front axle 21F to which the front wheels 7F are attached.

The first clutch 17 and the second clutch 18 are composed of hydraulic clutches or the like. An oil passage is connected to the first clutch 17 , and the oil passage is connected to a first operating valve 25 to which hydraulic oil discharged from a hydraulic pump 33 is supplied. The first clutch 17 switches between a connected state and a disconnected state depending on the degree of opening of the first operating valve 25 . An oil passage is connected to the second clutch 18 , and the oil passage is connected to a second operating valve 26 . The second clutch 18 switches between a connected state and a disconnected state depending on the degree of opening of the second operating valve 26 . The first operating valve 25 and the second operating valve 26 are, for example, two-position switching valves with electromagnetic valves, and are switched between a connected state and a disconnected state by energizing or demagnetizing the solenoids of the electromagnetic valves.

When the first clutch 17 is in the disengaged state and the second clutch 18 is in the engaged state, the power of the shuttle shaft 12 is transmitted to the front wheels 7F through the second clutch 18 . As a result, the front wheels 7F and the rear wheels 7R are four-wheel drive (4WD) driven by power, and the rotational speeds of the front wheels 7F and the rear wheels 7R are substantially the same (4WD constant speed state). On the other hand, when the first clutch 17 is in the engaged state and the second clutch 18 is in the disengaged state, four-wheel drive is established and the rotation speed of the front wheels 7F becomes faster than the rotation speed of the rear wheels 7R (4WD acceleration state). ). Also, when the first clutch 17 and the second clutch 18 are in the engaged state, the power of the shuttle shaft 12 is not transmitted to the front wheels 7F, so that the rear wheels 7R are two-wheel drive (2WD) driven by the power.

The tractor 1 has a positioning device 40 . The positioning device 40 can detect its own position (positioning information including latitude and longitude) using satellite positioning systems (positioning satellites) such as D-GPS, GPS, GLONASS, Hokuto, Galileo, and Michibiki. That is, the positioning device 40 receives satellite signals (position of the positioning satellite, transmission time, correction information, etc.) transmitted from the positioning satellite, and detects the position (for example, latitude and longitude) based on the satellite signal. The positioning device 40 has a receiving device 41
and an inertial measurement unit (IMU: Inertial Measurement Unit) 42 . The receiving device 41 is a device that has an antenna or the like and receives satellite signals transmitted from a positioning satellite, and is attached to the vehicle body 3 separately from the inertial measurement device 42 . In this embodiment, the receiving device 41 is attached to a rope provided on the vehicle body 3 . Note that the mounting location of the receiving device 41 is not limited to the embodiment.

The inertial measurement device 42 has an acceleration sensor that detects acceleration, a gyro sensor that detects angular velocity, and the like. The roll angle, pitch angle, yaw angle, etc. of the vehicle body 3 can be detected by the inertial measurement device 42 provided below the vehicle body 3 , for example, the driver's seat 10 .
As shown in FIG. 1 , the tractor 1 has a steering device 11 . The steering device 11 is a device capable of manual steering in which the vehicle body 3 is steered by a driver's operation and automatic steering in which the vehicle body 3 is automatically steered without being operated by the driver.

The steering device 11 has a steering handle (steering wheel) 30 and a steering shaft (rotating shaft) 31 that rotatably supports the steering handle 30 . The steering device 11 also has an auxiliary mechanism (power steering device) 32 . The assist mechanism 32 assists the rotation of the steering shaft 31 (steering handle 30) by hydraulic pressure or the like. The auxiliary mechanism 32 includes a hydraulic pump 33 , a control valve 34 to which hydraulic oil discharged from the hydraulic pump 33 is supplied, and a steering cylinder 35 operated by the control valve 34 . The control valve 34 is, for example, a three-position switching valve that can be switched by movement of a spool or the like, and switches in accordance with the steering direction (rotational direction) of the steering shaft 31 . The steering cylinder 35 is connected to an arm (knuckle arm) 36 for turning the front wheels 7F.

Therefore, when the driver grips the steering handle 30 and operates it in one direction or the other, the switching position and the degree of opening of the control valve 34 are switched corresponding to the rotation direction of the steering handle 30, and the control valve 34 The steering direction of the front wheels 7F can be changed by extending and retracting the steering cylinder 35 to the left or right according to the switching position and opening degree of . In other words, the vehicle body 3 can change its traveling direction to the left or right by manually steering the steering handle 30 .

Next, automatic steering will be described.
As shown in FIG. 2, when performing automatic steering, first, a driving reference line L1 is set before performing automatic steering. After setting the driving reference line L1, automatic steering can be performed by setting a planned driving line L2 parallel to the driving reference line L1. In the automatic steering, the tractor 1 (body 3) is automatically steered in the direction of travel so that the vehicle body position measured by the positioning device 40 and the planned travel line L2 coincide with each other.

Specifically, before automatic steering is performed, the tractor 1 (body 3) is moved to a predetermined position in the field (S1), and the driver operates the steering switch 52 provided on the tractor 1 at the predetermined position. Then (S2), the vehicle body position measured by the positioning device 40 is set to the starting point P10 of the travel reference line L1 (S3). Further, the tractor 1 (body 3) is moved from the starting point P10 of the traveling reference line L1 (S4), and when the driver operates the steering changeover switch 52 at a predetermined position (S5), the positioning device 40 measures The vehicle body position is set at the end point P11 of the running reference line L1 (S6). Therefore, a straight line connecting the start point P10 and the end point P11 is set as the travel reference line L1.

After setting the traveling reference line L1 (after S6), for example, the tractor 1 (vehicle body 3) is moved to a location different from the location where the traveling reference line L1 is set (S7), and the driver operates the steering changeover switch 52. (S8), a planned travel line L2, which is a straight line parallel to the travel reference line L1, is set (S9). After the planned travel line L2 is set, automatic steering is started, and the traveling direction of the tractor 1 (body 3) is changed to follow the planned travel line L2. For example, if the current vehicle body position is on the left side of the planned travel line L2, the front wheels 7F are steered to the right. is steered to the left. During automatic steering, the running speed (vehicle speed) of the tractor 1 (vehicle body 3) can be changed by the driver manually changing the operation amount of the accelerator member (accelerator pedal, accelerator lever) provided on the tractor 1, It can be changed by changing the gear stage of the transmission 5 .

Further, after the automatic steering is started, the automatic steering can be terminated when the driver operates the steering changeover switch 52 at an arbitrary position. That is, the end point of the planned travel line L2 can be set by the end of automatic steering by operating the steering changeover switch 52 . That is, the length from the start point to the end point of the planned travel line L2 can be set longer or shorter than the travel reference line L1. In other words, the planned travel line L2 is not associated with the length of the reference travel line L1, and the planned travel line L2 allows the vehicle to travel a longer distance than the length of the reference travel line L1 while being automatically steered.

As shown in FIG. 1 , the steering device 11 has an automatic steering mechanism 37 . The automatic steering mechanism 37 is a mechanism for automatically steering the vehicle body 3 , and automatically steers the vehicle body 3 based on the position of the vehicle body 3 (vehicle position) detected by the positioning device 40 . The automatic steering mechanism 37 has a steering motor 38 and a gear mechanism 39 . The steering motor 38 is a motor whose rotation direction, rotation speed, rotation angle, etc. can be controlled based on the position of the vehicle body. The gear mechanism 39 includes a gear provided on the steering shaft 31 and rotating together with the steering shaft 31, and a gear provided on the rotating shaft of the steering motor 38 and rotating together with the rotating shaft. When the rotating shaft of the steering motor 38 rotates, the steering shaft 31 automatically rotates (turns) via the gear mechanism 39, and the steering direction of the front wheels 7F is adjusted so that the vehicle body position coincides with the planned travel line L2. can be changed.

As shown in FIG. 1, the tractor 1 has a display device 45 . The display device 45 is a device that can display various information about the tractor 1 , and can display at least the operation information of the tractor 1 . The display device 45 is provided in front of the driver's seat 10 .
As shown in FIG. 1 , the tractor 1 has a setting switch 51 . The setting switch 51 is a switch for switching to a setting mode in which at least settings before the start of automatic steering are performed. The setting mode is a mode in which various settings related to the automatic steering are performed before the automatic steering is started.

The setting switch 51 can be switched ON or OFF, and outputs a signal indicating that the setting mode is valid when it is ON, and outputs a signal indicating that the setting mode is invalid when it is OFF. The setting switch 51 outputs a signal indicating that the setting mode is valid to the display device 45 when it is ON, and outputs a signal indicating that the setting mode is invalid to the display device 45 when it is OFF.

The tractor 1 has a steering changeover switch 52 . The steering changeover switch 52 is a switch for switching between starting and ending automatic steering. Specifically, the steering selector switch 52 can be switched upward, downward, forward, or rearward from the neutral position, and when it is switched downward from the neutral position while the setting mode is valid, the automatic steering is started. When the setting mode is valid and the position is switched upward from the neutral position, the end of the automatic steering is output. Further, when the steering changeover switch 52 is switched from the neutral position to the rear while the setting mode is valid, the steering changeover switch 52 outputs to set the current vehicle body position to the start point P10 of the traveling reference line L1, and the steering changeover switch 52 52 outputs that the current vehicle body position is set to the end point P11 of the running reference line L1 when the neutral position is switched forward while the setting mode is valid.

The tractor 1 has a correction switch 53 . The correction switch 53 is a switch for correcting the vehicle body position (latitude, longitude) measured by the positioning device 40 . That is, the correction switch 53 is used to calculate the vehicle body position (calculated vehicle body position) from the satellite signals (position of the positioning satellite, transmission time, correction information, etc.) and measurement information (acceleration, angular velocity) measured by the inertial measurement device 42. ) is a switch for correcting

The correction switch 53 is composed of a depressible push switch or a slidable slide switch. A case where the correction switch 53 is a push switch or a slide switch will be described below.
When the correction switch 53 is a push switch, the correction amount is set based on the number of times the push switch is operated. The correction amount is determined by correction amount=number of operations×correction amount per one operation. For example, as shown in FIG. 3A, the correction amount increases by several centimeters or several tens of centimeters each time the push switch is operated. The number of push switch operations is input to the first control device 60A, and the first control device 60A sets (calculates) the correction amount based on the number of operations.

Further, when the correction switch 53 is a slide switch, the correction amount is set based on the operation amount (displacement amount) of the slide switch. For example, the correction amount is determined by correction amount=displacement amount from a predetermined position. For example, as shown in FIG. 3B, every time the displacement amount of the slide switch increases by 5 mm, the correction amount increases by several centimeters or several tens of centimeters. The operation amount (displacement amount) of the slide switch is input to the first control device 60A, and the first control device 60A sets (calculates) the correction amount based on the displacement amount. It should be noted that the method of increasing the correction amount and the rate of increase described above are not limited to the numerical values described above.

Specifically, as shown in FIGS. 4A and 4B, the correction switch 53 has a first correction section 53A and a second correction section 53B. The first correction section 53A is a section that commands correction of the vehicle body position corresponding to one side in the width direction of the vehicle body 3, that is, the left side. The second correction section 53B is a section that commands correction of the vehicle body position corresponding to the other side in the width direction of the vehicle body 3, that is, the right side.

As shown in FIG. 4A, when the correction switch 53 is a push switch, the first correction section 53A and the second correction section 53B are ON or OFF switches that automatically return each time they are operated. The switches forming the first correction section 53A and the switches forming the second correction section 53B are integrated. The switches forming the first correction section 53A and the switches forming the second correction section 53B may be arranged apart from each other. As shown in FIG. 3A, each time the first correction portion 53A is pressed, the correction amount corresponding to the left side of the vehicle body 3 (left correction amount) increases. Also, every time the second correction portion 53B is pressed, the correction amount corresponding to the right side of the vehicle body 3 (right correction amount) increases.

As shown in FIG. 4B, when the correction switch 53 is a slide switch, the first correction portion 53A and the second correction portion 53B include a knob portion 55 that moves left or right along the longitudinal direction of the slot. there is When the correction switch 53 is a slide switch, the first correction portion 53A and the second correction portion 53B are arranged apart from each other in the width direction. As shown in FIG. 3B, when the knob portion 55 is gradually displaced leftward from a predetermined reference position, the left correction amount increases according to the amount of displacement. Further, when the knob portion 55 is gradually displaced to the right from the predetermined reference position, the right correction amount increases according to the amount of displacement. As shown in FIG. 4B, in the case of a slide switch, the first correction portion 53A and the second correction portion 53B are integrally formed, the reference position of the knob portion 55 is set at the center, and the The left correction amount may be set when the knob 55 is moved to the left, and the right correction amount may be set when the knob 55 is moved to the right from the intermediate position.

Next, the relationship between the correction amount (left correction amount, right correction amount) by the correction switch 53, the planned travel line L2, and the behavior (travel locus) of the tractor 1 (vehicle body 3) will be described.
FIG. 5A shows a state in which the calculated vehicle body position W1 deviates to the right while the vehicle is traveling straight under automatic steering. As shown in FIG. 5A, when the automatic steering is started, the actual position (actual position W2) of the tractor 1 (vehicle body 3) and the calculated vehicle body position W1 match, and the actual position W2 and the planned travel line If L2 matches, the tractor 1 travels along the planned traveling line L2. That is, in the section P1 where there is no positioning error in the positioning device 40 and the vehicle body position (calculated vehicle body position W1) detected by the positioning device 40 is the same as the actual position W2, the tractor 1 travels along the scheduled travel line L2. . When there is no error in positioning by the positioning device 40 and no correction is performed, the calculated vehicle body position W1 and the corrected vehicle body position (corrected vehicle body position) W3 are the same. The corrected vehicle body position W3 is the corrected vehicle body position W3=calculated vehicle body position W1−correction amount.

Here, in the vicinity of the position P20, although the actual position W2 is not deviated from the planned travel line L2, due to various influences, an error occurs in the positioning of the positioning device 40, and the position is detected by the positioning device 40. If the vehicle body position W1 deviates to the right with respect to the planned travel line L2 (actual position W2) and the deviation amount W4 is maintained, the tractor 1 will be operated in such a manner that there is a deviation between the calculated vehicle body position W1 and the planned travel line L2. Then, the tractor 1 is steered to the left so as to eliminate the amount of deviation W4 between the calculated vehicle body position W1 and the planned travel line L2. Then, the actual position W2 of the tractor 1 is shifted to the planned travel line L2 by left steering. Assume that the driver thereafter notices that the tractor 1 is deviated from the planned travel line L2, and steers the second correction unit 53B at position P21 to increase the right correction amount from zero. A right correction amount is added to the calculated vehicle body position W1, and the vehicle body position after correction (corrected vehicle body position) W3 can be substantially the same as the actual position W2. That is, by setting the right correction amount by the second correction unit 53B, the vehicle body position of the positioning device 40 can be corrected in the direction of eliminating the deviation amount W4 generated near the position P20. As indicated by position P21 in FIG. 5A, when the actual position W2 of the tractor 1 is away from the planned travel line L2 to the left after correcting the vehicle body position, the tractor 1 is steered to the right. The actual position W2 can be matched with the planned travel line L2.

FIG. 5B shows a state in which the calculated vehicle body position W1 deviates to the left while the vehicle is traveling straight under automatic steering. As shown in FIG. 5B, when the actual position W2 and the calculated vehicle body position W1 match and the actual position W2 and the planned travel line L2 match in a state in which the automatic steering is started, as shown in FIG. Similarly, the tractor 1 travels along the scheduled travel line L2. 5A, the tractor 1 travels along the scheduled travel line L2 in the section P2 where the positioning device 40 has no positioning error. Further, similarly to FIG. 5A, the calculated vehicle body position W1 and the corrected vehicle body position W3 are the same value.

Here, at the position P22, various influences cause an error in the positioning of the positioning device 40, causing the vehicle body position W1 detected by the positioning device 40 to deviate to the left with respect to the actual position W2, and the deviation amount W5 is maintained. If so, the tractor 1 is steered to the right so as to eliminate the amount of deviation W5 between the calculated vehicle body position W1 and the planned travel line L2. After that, assume that the driver notices that the tractor 1 is deviated from the planned travel line L2 and steers the first correction unit 53A at position P23 to increase the left correction amount from zero. Then, the left correction amount is added to the calculated vehicle body position W1, and the vehicle body position after correction (corrected vehicle body position) W3 can be substantially the same as the actual position W2. That is, by setting the left correction amount by the first correction unit 53A, the vehicle body position of the positioning device 40 can be corrected in the direction of eliminating the deviation amount W5 generated near the position P22. As indicated by position P23 in FIG. 5B, when the actual position W2 of the tractor 1 is away from the planned travel line L2 to the right after correcting the vehicle body position, the tractor 1 is steered to the left. The actual position W2 can be matched with the planned travel line L2.

Next, the setting switch 51 and the correction switch 53 will be explained.
As shown in FIG. 6, the outer circumference of the steering shaft 31 is covered with a steering post 180. As shown in FIG. The outer circumference of steering post 180 is covered with cover 177 . The cover 177 is provided in front of the driver's seat 10 . Cover 177 includes panel cover 178 and column cover 179 .

A panel cover 178 supports the display device 45 . A support portion 178 e that supports the display device 45 is provided on the upper plate portion 178 a of the panel cover 178 . The support portion 178 e supports the display device 45 in front of the steering shaft 31 and below the steering handle 30 . The upper plate portion 178a also has a mounting surface 178f on which the setting switch 51 and the correction switch 53 are mounted. The mounting surface 178f is provided behind the support portion 178e and below the steering handle 30. As shown in FIG. The support portion 178e and the mounting surface 178f are continuous, the support portion 178e being positioned in front of the upper plate portion 178a, and the mounting surface 178f being positioned in the rear portion of the upper plate portion 178a. The setting switch 51 and the correction switch 53 are attached to the attachment surface 178f. Accordingly, the setting switch 51 and the correction switch 53 are arranged around the steering shaft 31 .

A shuttle lever 181 protrudes from the left plate portion 178b of the panel cover 178. As shown in FIG. The shuttle lever 181 is a member that operates to switch the running direction of the vehicle body 3 . More specifically, by operating (swinging) the shuttle lever 181 forward, the forward/reverse switching unit 13 is brought into a state of outputting forward driving power to the traveling device 7, and the traveling direction of the vehicle body 3 is switched to the forward direction. Further, by operating (swinging) the shuttle lever 181 rearward, the forward/reverse switching portion 13 is brought into a state of outputting reverse driving power to the traveling device 7, and the traveling direction of the vehicle body 3 is switched to the backward traveling direction. Power is not output to the traveling device 7 when the shuttle lever 181 is in the neutral position.

The column cover 179 is arranged below the steering handle 30 and covers the upper portion of the steering shaft 31 . The column cover 179 is formed in a substantially square tubular shape and protrudes upward from the mounting surface 178f of the panel cover 178. As shown in FIG. That is, the mounting surface 178f is provided around the column cover 179. As shown in FIG. Therefore, the setting switch 51 and the correction switch 53 attached to the attachment surface 178f are arranged around the column cover 179. As shown in FIG.

Next, the arrangement of the setting switch 51, the steering switch 52, and the correction switch 53 will be described in detail. As shown in FIG. 6 , the setting switch 51 , the steering changeover switch 52 and the correction switch 53 are arranged around the steering shaft 31 .
The setting switch 51 is arranged on one side (left side) of the steering shaft 31 . The steering changeover switch 52 is arranged on one side (left side) of the steering shaft 31 . In the case of this embodiment, the steering changeover switch 52 is composed of a swingable lever. The steering changeover switch 52 can swing around a base end provided on the steering shaft 31 side as a fulcrum. A base end portion of the steering changeover switch 52 is provided inside the column cover 179 . The steering switch 52 protrudes to one side (left) of the column cover 179 .

The correction switch 53 is arranged on the other side (right side) of the steering shaft 31 . More specifically, the correction switch 53 is arranged to the right and rear (diagonally right rear) of the steering shaft 31 . The correction switch 53 is arranged to the right and rear (diagonally right rear) of the column cover 179 in terms of positional relationship with the column cover 179 . The correction switch 53 is arranged on the rear right side of the mounting surface 178f of the panel cover 178 in terms of the positional relationship with the mounting surface 178f. By arranging the correction switch 53 at the rear portion of the inclined mounting surface 178f, a long distance between the correction switch 53 and the steering handle 30 can be ensured. As a result, unintended operation of the correction switch 53 and steering of the steering wheel 30 can be prevented more reliably.

As described above, the setting switch 51 , the steering changeover switch 52 and the correction switch 53 are arranged around the steering shaft 31 . In other words, the setting switch 51 , the steering switch 52 , and the correction switch 53 are concentrated around the steering shaft 31 . Therefore, the driver can grasp the position of each switch at a glance. In addition, the driver can operate each switch while seated on the driver's seat 10 without changing his/her posture. Therefore, operability is improved, and erroneous operations can be prevented. Moreover, the harness (wiring) routed from each switch can be shortened.

Incidentally, regarding the arrangement of the switches described above, the left and right sides may be interchanged. That is, one side may be the left side and the other side may be the right side, or one side may be the right side and the other side may be the left side. Specifically, for example, the setting switch 51 and the steering changeover switch 52 may be arranged on the right side of the steering shaft 31 and the correction switch 53 may be arranged on the left side of the steering shaft 31 .

As shown in FIG. 1 , the tractor 1 has a plurality of control devices 60 . The plurality of control devices 60 are devices that perform travel system control, work system control, vehicle body position calculation, and the like in the tractor 1 . The plurality of control devices 60 are a first control device 60A, a second control device 60B and a third control device 60C.
The first control device 60A receives the satellite signal (received information) received by the receiver 41 and the measurement information (acceleration, angular velocity, etc.) measured by the inertial measurement device 42, and determines the position of the vehicle body based on the received information and the measurement information. Ask for For example, when the amount of correction by the correction switch 53 is zero, that is, when correction of the vehicle body position by the correction switch 53 is not commanded, the first control device 60A calculates the calculated vehicle body position calculated from the received information and the measured information. Without correcting the position W1, the calculated vehicle body position W1 is determined as the vehicle body position used during automatic steering. On the other hand, when correction of the vehicle body position by the correction switch 53 is commanded, the first control device 60A corrects the vehicle body position based on either the number of operations of the correction switch 53 or the operation amount (displacement amount) of the correction switch 53. A correction amount is set, and a corrected vehicle body position W3 obtained by correcting the calculated vehicle body position W1 with the correction amount is determined as a vehicle body position to be used during automatic steering.

The first control device 60A sets a control signal based on the vehicle body position (calculated vehicle body position W1, corrected vehicle body position W3) and the planned travel line L2, and outputs the control signal to the second control device 60B. The second control device 60B has an automatic steering control section 200. As shown in FIG. The automatic steering control unit 200 is composed of an electrical/electronic circuit provided in the second control device 60B, a program stored in a CPU, and the like. The automatic steering control unit 200 controls the steering motor 38 of the automatic steering mechanism 37 so that the vehicle body 3 travels along the scheduled travel line L2 based on the control signal output from the first control device 60A.

As shown in FIG. 7, the automatic steering control unit 200 maintains the rotation angle of the rotation shaft of the steering motor 38 when the deviation between the vehicle body position and the planned travel line L2 is less than the threshold. When the deviation between the vehicle body position and the planned travel line L2 is greater than or equal to the threshold and the tractor 1 is positioned on the left side of the planned travel line L2, the automatic steering control unit 200 controls the steering direction of the tractor 1 to the right. The rotating shaft of the steering motor 38 is rotated so as to be in the direction. When the deviation between the vehicle body position and the planned travel line L2 is greater than or equal to the threshold and the tractor 1 is positioned on the right side of the planned travel line L2, the automatic steering control unit 200 controls the steering direction of the tractor 1 to the left. The rotating shaft of the steering motor 38 is rotated so as to be in the direction. In the above-described embodiment, the steering angle of the steering device 11 is changed based on the deviation between the vehicle body position and the planned travel line L2. If the orientation (vehicle orientation) F1 (traveling direction) is different, that is, if the angle θg of the vehicle orientation F1 with respect to the planned travel line L2 is equal to or greater than the threshold, the automatic steering control unit 200 controls the angle θg to be zero (vehicle orientation). The steering angle may be set so that F1 coincides with the direction of the planned travel line L2. Further, the automatic steering control unit 200 sets the final steering angle in automatic steering based on the steering angle obtained based on the deviation (positional deviation) and the steering angle obtained based on the bearing (bearing deviation). may The setting of the steering angle in the automatic steering in the embodiment described above is an example, and is not limited.

The third control device 60</b>C raises and lowers the connecting portion 8 according to the operation of the operating member provided around the driver's seat 10 . Note that the first control device 60A, the second control device 60B, and the third control device 60C may be integrated. Further, the control of the traveling system, the control of the work system, and the calculation of the vehicle body position described above are not limited.
As described above, the control device 60 can automatically steer the tractor 1 (the vehicle body 3).

As described above, the tractor 1 (body 3) during automatic steering performs automatic steering so as to zero (reduce) either the position deviation or the azimuth deviation between the vehicle body 3 and the planned travel line L2. As shown in FIG. 8, the control device 60 (first control device 60A) determines a position closer to the vehicle body 3 than the planned travel line L2 when performing automatic steering, that is, the vehicle body position (calculated vehicle body position W1, corrected vehicle body position W3) and the planned travel line L2, a target travel line ALn (n=1, 2, 3, . . . ) is set. The target travel line ALn is a straight line substantially parallel to the scheduled travel line L2.

The first control device 60A has a target line setting section 213 . The target line setting unit 213 is composed of electrical/electronic components provided in the control device 60, programs incorporated in the control device 60, and the like. The target line setting unit 213 sets the target travel line ALn when the positional deviation is equal to or greater than a predetermined value.
FIG. 8 shows a travel locus K1 of a tractor 1 that does not have a target line setting unit 213 (hereinafter referred to as a normal tractor) and a travel path of a tractor 1 that has a target line setting unit 213 (hereinafter referred to as a main tractor). locus K2. The tractor 1 (normal tractor, main tractor) is separated from the planned travel line L2 by a position deviation Δx and has a zero azimuth deviation, that is, is shifted to the left of the planned travel line L2 by a position deviation Δx, and is above the point P20. is present in

When the tractor normally performs automatic steering, the vehicle body 3 advances while the steering angle is set by the steering device 11 so as to approach the planned travel line L2.
On the other hand, when the tractor performs automatic steering, the target line setting unit 213 determines the current vehicle body position ( A target travel line AL1 (n=1) is set between the point P20) and the planned travel line L2. The target line setting unit 213 sets a target travel line AL1 parallel to the scheduled travel line L2 at a position separated by a set distance X1 from the point P20.

After the target line setting unit 213 sets the target travel line AL1, the automatic steering control unit 200 of the second control device 60B sets the steering angle and steering direction of the steering device 11 so that the vehicle body 3 approaches the target travel line AL1. Execute autopilot. After automatic steering based on the target travel line AL1, the target line setting unit 213 determines whether the position deviation Δx at an arbitrary point is greater than the first set determination value. is also larger, the target line setting unit 213 resets, for example, a new target travel line AL2 (n=2) between the point P21 and the planned travel line L2. After resetting the new target travel line AL2, the automatic steering control unit 200 of the second control device 60B sets the steering angle and steering direction of the steering device 11 so that the vehicle body 3 approaches the target travel line AL2. to run. After setting the target travel line AL2, the target line setting unit 213 stops resetting the target travel line ALn when the positional deviation Δx at an arbitrary point is smaller than the first set determination value. When the resetting of the target travel line ALn is stopped, the tractor automatically steers according to the scheduled travel line L2.

That is, the target line setting unit 213 repeats resetting of the target travel line ALn until the positional deviation Δx between the current vehicle body position and the planned travel line L2 becomes smaller than the first set determination value. performs automatic steering so that the vehicle body 3 approaches the reset target travel line ALn.
As described above, when automatic steering is performed while resetting the target travel line ALn, the travel locus K2 of the tractor in the automatic steering draws a relatively smoother locus than the travel locus K1 of the normal tractor. become. That is, when the normal tractor and the main tractor automatically steer toward the planned travel line L2, the steering angle of the main tractor traveling toward the target travel line ALn can be made smaller than the steering angle of the normal tractor. Therefore, the tractor can be gradually brought closer to the scheduled travel line L2.

Next, a case where the target line setting unit 213 resets the target travel line based on the travel distance of the tractor 1 (vehicle body 3) will be described.
The control device 60 includes a distance calculator 214 that calculates the traveling distance of the vehicle body 3 . The distance calculation unit 214 is composed of electrical/electronic components provided in the control device 60, programs incorporated in the control device 60, and the like. The distance calculation unit 214 obtains, for example, the travel distance from the point where the target line setting unit 213 sets the target travel line ALn to the current vehicle body 3 . Based on the odometer provided on the tractor 1 , the distance calculation unit 214 obtains the distance traveled from the point where the target travel line ALn is set by the target line setting unit 213 to the current vehicle body 3 . The distance calculator 214 calculates the traveled distance from the difference between the odometer value at the point where the target travel line ALn is set by the target line setting unit 213 and the odometer value after a predetermined time.

Note that the distance calculation unit 214 calculates the difference between the vehicle body position detected by the positioning device 40 when the target line setting unit 213 sets the target travel line ALn and the vehicle body position detected by the positioning device 40 after a predetermined time. The travel distance may be calculated by calculation.
The target line setting unit 213 resets the target travel line ALn when the travel distance calculated by the distance calculation unit 214 exceeds a threshold while the automatic steering control unit 200 is executing automatic steering based on the target travel line ALn. conduct.

FIG. 9A is a diagram showing the travel locus K2 of the tractor 1 when automatic steering is performed while following the target travel line ALn based on the travel distance Lx. As shown in FIG. 9A, the tractor 1 (vehicle body 3) is traveling by automatic steering, and is located at a point LP0 with a positional deviation Δx on the left side of the planned traveling line L2. At this time, since the positional deviation Δx at the point LP0 is equal to or greater than the predetermined first set determination value (determination distance Jx), the target line setting unit 213 moves from the vehicle body 3 (point LP0) toward the planned travel line L2. A target travel line AL1 is set at a position separated by a set distance X1. When the target travel line AL1 is set, the automatic steering control unit 200 performs automatic steering according to the target travel line AL1.

After automatic steering based on the target travel line AL1 is started by the automatic steering control unit 200, the target line setting unit 213 calculates the travel distance Lx calculated by the distance calculation unit 214 (from the point LP0 where the target travel line AL1 is set to the current vehicle body 3 Monitor the traveled distance Lx) to For example, when the travel distance Lx at the point LP1 is greater than or equal to the threshold and the positional deviation Δx2 between the vehicle body 3 and the planned travel line L2 is greater than or equal to the first set determination value (determination distance Jx), the target line setting unit 213 sets the target travel line Reset ALn. The target line setting unit 213 sets a target travel line AL2 at a position separated by a set distance X1 from the vehicle body 3 (point LP1) toward the planned travel line L2. When the target travel line AL2 is set, the automatic steering control unit 200 performs automatic steering according to the target travel line AL2.

After the automatic steering control unit 200 starts automatic steering based on the target travel line AL2, the target line setting unit 213 monitors the travel distance Lx from the point LP1 to the current vehicle body 3. For example, when the travel distance Lx is equal to or greater than the threshold value at the point LP2, the target line setting unit 213 determines whether the positional deviation Δx3 between the vehicle body 3 and the scheduled travel line L2 is greater than or equal to the first set determination value (determination distance Jx). determine whether or not Here, the target line setting unit 213 stops resetting the target travel line ALn when the positional deviation Δx3 is not equal to or greater than the first set determination value (determination distance Jx). After stopping the resetting of the target travel line ALn, the automatic steering control unit 200 performs automatic steering along the scheduled travel line L2.

FIG. 9B shows the flow of the tractor 1 when automatic steering is performed while performing the target travel line ALn based on the travel distance Lx.
When automatic steering of the tractor 1 (vehicle body 3) is started (S21), the target line setting unit 213 determines that the positional deviation Δx between the current vehicle body position and the planned travel line L2 is greater than or equal to the determination distance Jx of the target travel line setting. is confirmed (S22).

If the positional deviation Δx is less than the judgment distance Jx (S22, No), the target line setting unit 213 does not set the target travel line ALn, or stops resetting the target travel line ALn ( S26). The automatic steering control unit 200 performs automatic steering according to the planned travel line L2 (S27). On the other hand, if the positional deviation Δx is greater than or equal to the judgment distance Jx (S22, Yes), the target line setting unit 213 sets the target travel line to a position a set distance X1 away from the vehicle body 3 toward the planned travel line L2. ALn is set (S23).

When the target travel line ALn is set, the tractor 1 (control device 60) performs automatic steering according to the target travel line (S24). During automatic steering, the target line setting unit 213 determines whether or not the traveling distance Lx is equal to or greater than a threshold (S25). When the travel distance Lx is less than the threshold value (S25, No), the target line setting unit 213 does not proceed to the process of resetting the target travel line ALn, and the automatic steering control unit 200 automatically adjusts the target travel line ALn based on the target travel line ALn. Steering is continued (S24).

If the travel distance Lx is equal to or greater than the threshold (S25, Yes), and if the positional deviation Δx between the vehicle body 3 and the planned travel line L2 is greater than or equal to the judgment distance Jx (S22, Yes), the target line setting unit 213 , the target travel line ALn is reset at a position separated by the set distance X1 from the vehicle body 3 toward the scheduled travel line L2 (S23). If the positional deviation Δx is less than the judgment distance Jx (S22, No), the setting of the target travel line is stopped (S26).

Next, it will be described how the target line setting unit 213 resets or stops the target travel line ALn based on the positional deviation between the tractor 1 (body 3) and the target travel line ALn. For convenience of explanation, the positional deviation AX between the tractor 1 (vehicle body 3) and the target travel line ALn is referred to as the "first positional deviation", and the positional deviation between the tractor 1 (vehicle body 3) and the planned travel line L2 is referred to as ""second positional deviation".

The target line setting unit 213 sets the target travel line ALn each time the first positional deviation becomes smaller by a predetermined amount while the automatic steering control unit 200 is performing automatic steering.
FIG. 10A is a diagram showing the travel locus of the tractor 1 when automatic steering is performed while performing the target travel line ALn based on the first positional deviation.
The tractor 1 (vehicle body 3) is traveling by automatic steering, and is located at a point AP0 with a second positional deviation Δx on the left side of the planned traveling line L2. At this time, since the second positional deviation Δx at the point LP0 is equal to or greater than the predetermined first set determination value (determination distance Jx), the target line setting unit 213 sets the travel planned line L2 from the vehicle body 3 (point AP0). A target travel line AL1 is set at a position separated by a set distance X1 toward the target travel line AL1. When the target travel line AL1 is set, the automatic steering control unit 200 performs automatic steering according to the target travel line AL1.

After the automatic steering control unit 200 starts automatic steering based on the target travel line AL1, the target line setting unit 213 monitors the first position deviation AX. When the first positional deviation AX becomes smaller by a predetermined amount at the point AP1 and the second positional deviation Δx4 between the vehicle body 3 and the planned travel line L2 is equal to or greater than the first set determination value (determination distance Jx), the target line setting unit 213 The target travel line ALn is reset. The target line setting unit 213 sets a target travel line AL2 at a position separated by a set distance X1 from the vehicle body 3 (point AP1) toward the planned travel line L2. When the target travel line AL2 is set, the automatic steering control unit 200 performs automatic steering according to the target travel line AL2.

After the automatic steering control unit 200 starts automatic steering based on the target travel line AL2, the target line setting unit 213 monitors the second positional deviation AX between the current vehicle body 3 and the target travel line AL2. For example, when the second positional deviation AX becomes smaller by a predetermined amount at the point AP2, the target line setting unit 213 determines that the second positional deviation Δx5 between the vehicle body 3 and the planned travel line L2 is the first set determination value (determination distance Jx). It is determined whether or not the above is satisfied. Here, the target line setting unit 213 stops resetting the target travel line ALn when the second position deviation Δx5 is not equal to or greater than the first set determination value (determination distance Jx). After stopping the resetting of the target travel line ALn, the automatic steering control unit 200 performs automatic steering along the scheduled travel line L2.

FIG. 10B shows the flow of the tractor 1 when automatic steering is performed while following the target travel line ALn based on the second positional deviation AX.
When automatic steering of the tractor 1 (vehicle body 3) is started (S21), the target line setting unit 213 determines that the second positional deviation Δx between the current vehicle body position and the planned travel line L2 is equal to or greater than the determination distance Jx for setting the target travel line. (S22).

If the second positional deviation Δx is less than the judgment distance Jx (S22, No), the target line setting unit 213 does not set the target travel line ALn or stops resetting the target travel line ALn. (S26). The automatic steering control unit 200 performs automatic steering according to the planned travel line L2 (S27). On the other hand, if the second positional deviation Δx is greater than or equal to the judgment distance Jx (S22, Yes), the target line setting unit 213 sets the target position at a position a set distance X1 away from the vehicle body 3 toward the planned travel line L2. A running line ALn is set (S23).

When the target travel line ALn is set, the tractor 1 (control device 60) performs automatic steering according to the target travel line (S24). During automatic steering, the target line setting unit 213 determines whether or not the first positional deviation AX has decreased by a predetermined amount (S30). If the first positional deviation AX has not decreased by the predetermined amount (S30, No), the target line setting unit 213 does not proceed to the process of resetting the target travel line ALn, and the automatic steering control unit 200 resets the target travel line ALn. Automatic steering based on ALn is continued (S24).

When the first positional deviation AX has decreased by a predetermined amount (S30, Yes), if the second positional deviation Δx between the vehicle body 3 and the planned travel line L2 is greater than or equal to the judgment distance Jx (S22, Yes), The target line setting unit 213 resets the target travel line ALn to a position separated by the set distance X1 from the vehicle body 3 toward the planned travel line L2 (S23). If the second positional deviation Δx is less than the judgment distance Jx (S22, No), the setting of the target travel line is stopped (S26).

Next, a description will be given of when the target line setting unit 213 resets or cancels the target travel line based on the elapsed time.
The control device 60 includes a timer 215 that measures the elapsed time after setting the target travel line. The clock unit 215 is composed of electrical/electronic components provided in the control device 60, programs incorporated in the control device 60, and the like. The timer unit 215 measures the elapsed time from an arbitrary time point and transmits the elapsed time to the target line setting unit 213 .

The target line setting unit 213 resets the target travel line ALn when the elapsed time measured by the timer unit 215 exceeds a predetermined time while the automatic steering control unit 200 is executing automatic steering.
FIG. 11A is a diagram showing the travel locus of the tractor 1 when automatic steering is performed while performing the target travel line ALn based on the elapsed time.
The tractor 1 (body 3) is traveling by automatic steering, and is located at a point AP0 on the left side of the scheduled traveling line L2 with a second positional deviation Δx. At this time, since the positional deviation (second positional deviation) Δx at the point TP0 is equal to or greater than the predetermined first set determination value (determination distance Jx), the target line setting unit 213 sets the distance from the vehicle body 3 (point AP0) to A target travel line AL1 is set at a position away from the scheduled travel line L2 by a set distance X1. When the target travel line AL1 is set, the automatic steering control unit 200 performs automatic steering according to the target travel line AL1.

After automatic steering based on the target travel line AL1 is started by the automatic steering control unit 200, the target line setting unit 213 sets the elapsed time measured by the timer 215 (the first elapsed time after setting the target travel line AL1). to monitor. When the first elapsed time at the point TP1 is equal to or greater than a predetermined time and the second positional deviation Δx6 between the vehicle body 3 and the planned travel line L2 is greater than or equal to the first set determination value (determination distance Jx), the target line setting unit 213 sets the target travel Reset the line ALn. The target line setting unit 213 sets a target travel line AL2 at a position separated by a set distance X1 from the vehicle body 3 (point AP1) toward the planned travel line L2. When the target travel line AL2 is set, the automatic steering control unit 200 performs automatic steering according to the target travel line AL2.

After the automatic steering control unit 200 starts automatic steering based on the target travel line AL2, the target line setting unit 213 monitors a second elapsed time after setting the target travel line AL2. For example, when the second elapsed time is equal to or longer than the predetermined time at the point TP2, the target line setting unit 213 sets the second positional deviation Δx6 between the vehicle body 3 and the planned travel line L2 to be equal to or greater than the first set determination value (determination distance Jx). Determine whether or not Here, the target line setting unit 213 stops resetting the target travel line ALn when the second position deviation Δx6 is not equal to or greater than the first set determination value (determination distance Jx). After stopping the resetting of the target travel line ALn, the automatic steering control unit 200 performs automatic steering along the scheduled travel line L2.

FIG. 11B shows the flow of the tractor 1 when automatic steering is performed while driving the target travel line ALn based on the elapsed time.

When automatic steering of the tractor 1 (vehicle body 3) is started (S21), the target line setting unit 213 determines that the second positional deviation Δx between the current vehicle body position and the planned travel line L2 is equal to or greater than the determination distance Jx for setting the target travel line. (S22).

If the second positional deviation Δx is less than the judgment distance Jx (S22, No), the target line setting unit 213 does not set the target travel line ALn or stops resetting the target travel line ALn. (S26). The automatic steering control unit 200 performs automatic steering according to the planned travel line L2 (S27). On the other hand, if the second positional deviation Δx is greater than or equal to the judgment distance Jx (S22, Yes), the target line setting unit 213 sets the target position at a position a set distance X1 away from the vehicle body 3 toward the planned travel line L2. A running line ALn is set (S23).

When the target travel line ALn is set, the tractor 1 (control device 60) performs automatic steering according to the target travel line (S24). During automatic steering, the target line setting unit 213 determines whether or not a predetermined time or more has passed since the target travel line ALn was set (S40).
. If the elapsed time is less than the predetermined time (S20, No), the target line setting unit 213 does not proceed to processing for resetting the target travel line ALn, and the automatic steering control unit 200 performs automatic steering based on the target travel line ALn. is continued (S24).

If the elapsed time is equal to or greater than a predetermined time (S20, Yes), and if the second positional deviation Δx between the vehicle body 3 and the planned travel line L2 is equal to or greater than the judgment distance Jx (S22, Yes), the target line setting unit 213 resets the target travel line ALn at a position separated by the set distance X1 from the vehicle body 3 toward the planned travel line L2 (S23). If the second positional deviation Δx is less than the judgment distance Jx (S22, No), the setting of the target travel line is stopped (S26).

In the above-described embodiment, three conditions (travel distance, positional deviation, elapsed time) for resetting the target travel line ALn are presented, but these may be used in combination. The target travel line may be reset when either the travel distance of the tractor 1 (body 3) or the amount of change in the positional deviation reaches a predetermined amount, or the travel distance of the tractor 1 or the elapsed time. reaches a predetermined amount, the target travel line may be reset. Alternatively, the target travel line may be reset when either the amount of change in the positional deviation of the tractor 1 or the elapsed time reaches a predetermined amount.

The work vehicle 1 includes a steering device 11 that steers the vehicle body 3, a positioning device 40 that detects the position of the vehicle body 3, and controls automatic steering in the steering device 11 so as to reduce the deviation between the vehicle body 3 and the planned travel line. a control device 60, the control device 60 being a target line setting unit 213 for setting a target travel line ALn between the vehicle body position, which is the position of the vehicle body 3 detected by the positioning device 40, and the planned travel line L2; and an automatic steering control unit 200 that automatically steers the steering device 11 so that the vehicle body 3 heads toward the target travel line ALn before the vehicle body 3 reaches the planned travel line L2. According to this, the target travel line ALn can be set between the vehicle body position and the planned travel line L2 before the vehicle body 3 reaches the planned travel line L2. For example, when the vehicle body 3 and the planned travel line L2 are separated from each other, the vehicle body 3 can perform automatic steering with respect to the target travel line ALn, so that the traveling behavior of the vehicle body 3 can be stabilized. In other words, compared to the case where the target travel line ALn is not set, the steering angle of the steering device 11 toward the target travel line ALn can be made gentler, so movement (driving) from the current position to the planned travel line L2 can be reduced. can be done smoothly.

The target line setting unit 213 sets the target travel line ALn when the deviation is greater than or equal to a predetermined value. According to this, it is easy to set the target travel line ALn. That is, the target travel line ALn can be set when the positional deviation is large as the deviation.
The work vehicle 1 includes a distance calculation unit 214 that calculates the travel distance of the vehicle body 3. The target line setting unit 213 calculates the travel distance calculated by the distance calculation unit 214 while the automatic steering control unit 200 is executing automatic steering. exceeds the threshold, the target travel line ALn is reset. According to this, the target travel line ALn is set based on the travel distance of automatic steering. That is, the target travel line ALn can be reset every time the vehicle body 3 travels a predetermined travel distance, and the vehicle body 3 can be gradually brought closer to the scheduled travel line L2 each time the travel distance travels.

The target line setting unit 213 resets the target travel line ALn each time the deviation becomes smaller by a predetermined amount while the automatic steering control unit 200 is performing automatic steering. According to this, when the automatic steering is performed, the target travel line ALn can be reset every time the deviation between the vehicle body 3 and the line (planned travel line L2, target travel line) becomes small. can be gradually brought closer to the planned travel line L2.

The work vehicle 1 is provided with a timer 215 that measures the elapsed time after setting the target travel line ALn. When the elapsed time measured by 215 exceeds a predetermined time, the target travel line ALn is reset. According to this, when the automatic steering is performed, the target travel line ALn can be reset every predetermined time, and the vehicle body 3 can be gradually brought closer to the planned travel line L2.

The target line setting unit 213 ends the setting of the target travel line ALn when the deviation is less than the predetermined value. According to this, in a situation where the target travel line ALn is set repeatedly, automatic steering based on the target travel line ALn can be easily switched to automatic steering based on the planned travel line L2.
The work vehicle 1 includes a steering handle 30 for steering the vehicle body 3 by manual steering, and a steering selector switch 52 for switching between starting and ending automatic steering. According to this, it is possible to easily switch between automatic steering and manual steering by switching the steering selector switch 52 .

It should be considered that the embodiments disclosed this time are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the scope of the claims rather than the above description, and is intended to include all modifications within the scope and meaning equivalent to the scope of the claims.

REFERENCE SIGNS LIST 1 work vehicle 3 vehicle body 11 steering device 30 steering handle 40 positioning device 52 steering changeover switch (reference line setting switch)
60, 60A control device (first control device)
213 target line setting unit 214 distance calculation unit 215 timing unit ALn target travel line L1 travel reference line L2 scheduled travel line

Claims (6)

a steering device for steering a vehicle body;
a positioning device that detects the position of the vehicle body;
a control device for controlling automatic steering in the steering device so as to reduce the deviation between the vehicle body and the planned travel line;
with
The control device is
Between the vehicle body position, which is the position of the vehicle body detected by the positioning device, and the planned travel line, a target travel line parallel to the planned travel line is set at a position separated from the vehicle body position by a predetermined set distance . a target line setting unit;
an automatic steering control unit that automatically steers the steering device so that the vehicle body moves toward the target travel line before the vehicle body reaches the planned travel line;
has
The target line setting unit sets the target travel line when the deviation is equal to or greater than a predetermined value,
The automatic steering control unit executes the automatic steering of the vehicle body so as to approach the set target travel line,
After setting the target travel line, the target line setting unit determines whether the deviation is equal to or greater than the predetermined value each time a predetermined condition is satisfied while the automatic steering control unit is executing the automatic steering. and if the deviation is equal to or greater than a predetermined value, the target travel line is reset to a position separated by the set distance from the vehicle body position at that time, and the automatic steering control unit moves the target travel line to the reset target travel line. A work vehicle that performs said automatic steering of said vehicle body to approach . A distance calculation unit that calculates the travel distance of the vehicle body,
The target line setting unit determines that the predetermined condition is satisfied when the traveled distance calculated by the distance calculation unit exceeds a threshold while the automatic steering control unit is executing the automatic steering, and 2. The work vehicle according to claim 1, wherein it is determined whether or not the deviation is equal to or greater than the predetermined value in order to determine whether or not to reset the target travel line. The target line setting unit assumes that the predetermined condition is satisfied and resets the target travel line each time the deviation decreases by a predetermined amount while the automatic steering control unit is performing the automatic steering . The work vehicle according to claim 1 or 2, wherein it is determined whether or not the deviation is equal to or greater than the predetermined value . A timing unit for measuring the elapsed time after setting the target travel line,
The target line setting unit determines that the predetermined condition is satisfied when the elapsed time measured by the timer unit exceeds a predetermined time while the automatic steering control unit is executing the automatic steering, and the target line setting unit determines that the predetermined condition is satisfied. The work vehicle according to any one of claims 1 to 3 , wherein it is determined whether or not the deviation is equal to or greater than the predetermined value in order to determine whether or not to reset the travel line. The work vehicle according to any one of claims 1 to 4 , wherein the target line setting unit terminates setting of the target travel line when the deviation is less than the predetermined value . a steering handle for steering the vehicle body by manual steering;
a steering selector switch for switching between starting and ending the automatic steering;
The work vehicle according to any one of claims 1 to 5 , comprising:

Images