JP2022060517A - Work vehicle automatic traveling system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a work vehicle automatic traveling system capable of vehicle speed maintenance control considering a user's feeling of security and the like.

SOLUTION: A work vehicle automatic traveling system comprises an automatic traveling control unit. The automatic traveling control unit can make a work vehicle automatically travel along a travel route including a work route, to which work is to be performed by a work unit, and a turning route, by using a positioning system. The work vehicle comprises a vehicle speed control unit for controlling vehicle speed. The automatic traveling control unit permits vehicle speed maintaining control for maintaining, by the vehicle speed control unit, the predetermined vehicle speed in the case of making the work vehicle automatically travel along the work route, and meanwhile, prohibits the vehicle speed control unit from performing the vehicle speed maintaining control in the case of making the work vehicle automatically travel along the turning route.

SELECTED DRAWING: Figure 9

COPYRIGHT: (C)2022,JPO&INPIT

Description

The present invention relates to an automatic traveling system for a work vehicle.

Conventionally, there has been known a configuration capable of executing vehicle speed maintenance control (auto cruise control) for maintaining the vehicle speed of a work vehicle at a predetermined vehicle speed. Patent Document 1 discloses a speed holding mechanism as this kind of configuration.

In the speed holding mechanism of Patent Document 1, the motor of the continuously variable transmission driven and operated by the speed change operating tool is driven and stopped when the traveling speed holding mechanism is operated, and the speed holding operation tool is used to maintain the speed at an arbitrary speed. It is configured so that the release of speed holding can be operated.

Japanese Unexamined Patent Publication No. 2004-262417

By the way, in recent years, work vehicles capable of automatically traveling along a target route have been developed. In some such work vehicles, the steering operation along the target route is automatically performed during automatic driving, but the traveling vehicle speed is configured to follow the user's operation. It is also conceivable to apply the vehicle speed maintenance control as shown in Patent Document 1 to such a work vehicle.

However, in a work vehicle capable of automatically traveling along a target route, allowing the use of vehicle speed maintenance control during automatic driving without limitation is compared with the case where the user operates the steering by himself / herself to drive. Not always preferable.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an automatic traveling system for a work vehicle capable of maintaining and controlling a vehicle speed in consideration of a user's sense of security and the like.

The problem to be solved by the present invention is as described above, and next, the means for solving this problem and its effect will be described.

From the viewpoint of the present invention, an automatic traveling system for a work vehicle having the following configuration is provided. That is, the automatic traveling system of this work vehicle includes an automatic traveling control unit. The automatic traveling control unit uses a positioning system to create a traveling path having a plurality of work paths in which work is performed by the working unit and a turning path connecting adjacent work paths among the plurality of work paths. It is possible to automatically drive the work vehicle along the line. The work vehicle includes a vehicle speed control unit that controls the vehicle speed of the work vehicle. The automatic traveling control unit permits vehicle speed maintenance control for maintaining a predetermined vehicle speed by the vehicle speed control unit when the working vehicle is automatically driven along the work path, while the automatic traveling control unit permits the vehicle speed maintenance control along the turning path. When the work vehicle is automatically driven, the vehicle speed maintenance control by the vehicle speed control unit is prohibited.

As a result, when the work vehicle automatically travels on the turning path, the execution of the vehicle speed maintenance control is prohibited, so that the user himself / herself determines the vehicle speed when the work vehicle turns. Therefore, the cautiousness of turning can be ensured. Further, since the work vehicle generally does not work by the work unit when traveling along the turning path, it is possible to prevent deterioration of workability.

The automatic traveling system for the work vehicle preferably has the following configuration. That is, even when the work vehicle is automatically driven along the work path, the automatic travel control unit is in a section from a predetermined point to the end point, which is a predetermined distance before the end point of the work path. , The vehicle speed maintenance control by the vehicle speed control unit is prohibited.

When the work vehicle is traveling along the work path, the vehicle speed maintenance control is prohibited from the predetermined point where the remaining distance to the turn path is shortened, so that the user can manually operate from the stage before reaching the turn path. Will determine the vehicle speed. Therefore, the user's sense of security when the work vehicle turns on the turning path is improved.

The automatic traveling system for the work vehicle preferably has the following configuration. That is, when the automatic traveling control unit automatically travels the work vehicle along the work path while the vehicle speed maintenance control is being executed by the vehicle speed control unit, the position of the work vehicle is set. When the predetermined point is reached, the vehicle speed control unit is controlled to decelerate the work vehicle and then stop the work vehicle.

When the automatically traveling work vehicle reaches a predetermined point, the vehicle speed maintenance control is canceled. By controlling the deceleration of the work vehicle at this time, for example, it is possible to avoid a sudden stop and improve the riding comfort.

The automatic traveling system for the work vehicle preferably has the following configuration. That is, the automatic traveling control unit can cause the working vehicle to start automatic traveling along the working route when the automatic traveling start condition is satisfied. The automatic traveling start condition includes that the vehicle speed maintenance control is not executed by the vehicle speed control unit.

If automatic driving start is permitted while vehicle speed maintenance control is being executed, the working vehicle will change course at high speed depending on the positional relationship between the point where automatic driving is scheduled to start along the traveling route and the current position of the working vehicle. May do. By prohibiting the automatic start of traveling during the execution of the vehicle speed maintenance control, it is possible to move the work vehicle to the above-mentioned planned point while surely following the vehicle speed instruction by the user.

The automatic traveling system for the work vehicle preferably has the following configuration. That is, the automatic traveling system of this work vehicle includes an automatic traveling operation unit. The automatic traveling operation unit can issue a start command and an end command for automatic traveling of the work vehicle to the automatic traveling control unit. The automatic driving control unit operates the automatic driving operation unit when the work vehicle is automatically driven along the work path while the vehicle speed maintenance control is being executed by the vehicle speed control unit. When the automatic driving end command is given to the automatic driving control unit, the vehicle speed control unit is controlled to decelerate the work vehicle and then stop the work vehicle.

If the user instructs the end of automatic driving while the automatic driving is being performed on the work route while executing the vehicle speed maintenance control, and if the vehicle speed maintenance control is maintained, the user works to a point unintended. The vehicle may move forward. In this respect, according to the above configuration, the work vehicle can be stopped at a position close to the position at the time when the user instructs the end of the automatic traveling.

The automatic traveling system for the work vehicle preferably has the following configuration. That is, when the working vehicle is automatically driven along the turning path, the automatic traveling control unit controls the vehicle speed control unit regardless of the amount of operation of the vehicle speed operating unit to control the working vehicle. Limit the vehicle speed to below the specified upper limit vehicle speed.

As a result, the upper limit of the vehicle speed of the work vehicle is set on the turning path, so that the riding comfort can be improved.

The automatic traveling system for the work vehicle preferably has the following configuration. That is, when the automatically traveling work vehicle shifts from the turning path to the work path, the automatic travel control unit prevents the vehicle speed control unit from accelerating the work vehicle until a predetermined condition is satisfied. The predetermined condition is to operate the vehicle speed control unit on the deceleration side.

When the automatically traveling work vehicle shifts from the turning path to the working path, if the upper limit of the vehicle speed applied on the turning path is released, the working vehicle may accelerate against the intention of the user. In this regard, according to the above configuration, in order for the work vehicle that has moved to the work path to accelerate, it is necessary to explicitly operate the vehicle speed control unit to the deceleration side and then to the speed increase side. .. Therefore, it is possible to increase the user's sense of security regarding acceleration.

The side view of the rice transplanter used for the automatic traveling system of the work vehicle which concerns on one Embodiment of this invention. Plan view of rice transplanter. A skeleton diagram showing the power transmission configuration of a rice transplanter. Functional block diagram of rice transplanter and wireless communication terminal. The figure which shows an example of the automatic traveling route generated by the route generation part of a wireless communication terminal. A flowchart showing a process of determining whether or not to execute automatic control of the work unit. Flowchart of work part automatic control. The figure which shows a part of the automatic driving path. The flowchart which shows the process which determines whether or not the auto cruise control is executed. Flowchart of vehicle speed control including auto cruise control.

Next, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a side view of the rice transplanter 1. FIG. 2 is a plan view of the rice transplanter 1.

The automatic traveling system of a work vehicle according to an embodiment of the present invention includes a rice transplanter 1 shown in FIG. 1 as a work vehicle capable of automatically traveling. In the present embodiment, the rice transplanter is used as the work vehicle, but the present invention is not limited to this, and for example, a tractor or a combine can be used.

The automatic traveling system includes a wireless communication terminal 3 capable of remotely controlling the rice transplanter 1. In the present embodiment, the wireless communication terminal 3 is attached to an appropriate position of the rice transplanter 1 so that the user can operate the rice transplanter 1 while riding on the rice transplanter 1. However, the wireless communication terminal 3 can also be removed from the rice transplanter 1 and carried by the user.

The rice transplanter 1 can perform seedling planting work in the field. As shown in FIGS. 1 and 2, the rice transplanter 1 includes a vehicle body portion 11, a front wheel 12, a rear wheel 13, and a planting portion (working portion) 14. The front wheels 12 and the rear wheels 13 are provided in pairs with respect to the vehicle body portion 11, respectively.

The vehicle body portion 11 is configured as a traveling machine of the rice transplanter 1. The vehicle body portion 11 is provided with an engine 22 and a mission case 23. The engine 22 is supported by the front portion of the vehicle body portion 11. The mission case 23 is attached to the lower part of the vehicle body portion 11.

The driving force of the engine 22 is changed by the transmission case 23 and transmitted to the front wheels 12 and the rear wheels 13. Further, the driving force of the engine 22 is transmitted to the planting portion 14 via the mission case 23 and the PTO shaft 24 arranged at the rear portion of the vehicle body portion 11.

The vehicle body portion 11 can travel in a field or the like by transmitting the driving force of the engine 22 to the front wheels 12 and the rear wheels 13. The planting unit 14 can perform the work of planting seedlings in the field by transmitting the drive of the engine 22.

The vehicle body portion 11 is provided with a driver's seat 25 and a plurality of operating members. The driver's seat 25 is arranged between the front wheels 12 and the rear wheels 13 in the front-rear direction of the vehicle body portion 11. The user can sit in the driver's seat 25.

The plurality of operating members include a steering handle 26, a speed change pedal (vehicle speed operation unit) 27, a planting lift lever 28, a work unit automatic control on / off switch (operation unit) 69 described later, and an auto cruise lever (vehicle speed maintenance unit). Operation unit) 68 and.

The steering handle 26 is attached to a steering column arranged in front of the driver's seat 25. The user of the rice transplanter 1 can instruct the vehicle body portion 11 (rice transplanter 1) to go straight / turn by grasping and turning the steering handle 26 by hand.

The speed change pedal 27 is provided so as to project upward from the floor on the front side of the driver's seat 25. The speed change pedal 27 is rotatably supported at an appropriate position on the vehicle body portion 11. The user can operate the speed change pedal 27 by depressing it with his / her foot. The speed change pedal 27 is equipped with a return spring (not shown) for returning the speed change pedal 27 when the user releases the depression.

By depressing the speed change pedal 27, the user can instruct the vehicle body portion 11 (rice transplanter 1) to run. By changing the depth at which the user depresses the speed change pedal 27 with his / her foot, it is possible to instruct the acceleration / deceleration of the vehicle body portion 11 (instruct the vehicle speed). On the other hand, the user can instruct the rice transplanter 1 to stop running by taking his / her foot off the speed change pedal 27.

In the vehicle body portion 11, a pedal sensor 29 capable of detecting the operating position of the shifting pedal 27 is provided at an appropriate position with respect to the shifting pedal 27. The pedal sensor 29 can be configured as, for example, a potentiometer.

As shown in FIG. 1 and the like, the planting portion 14 is arranged behind the vehicle body portion 11. The planting section 14 can plant seedlings in the field. The planting portion 14 is connected to the vehicle body portion 11 via the elevating link mechanism 31.

An elevating cylinder 32 is provided between the vehicle body portion 11 and the planting portion 14. By expanding and contracting the elevating cylinder 32, the planting portion 14 can be moved up and down with respect to the vehicle body portion 11. The planting portion 14 may be raised or lowered by an actuator other than the cylinder.

The planting portion 14 can be moved up and down between a lowering position for performing the planting work and an ascending position for not performing the planting work. The descending position is a position where the planting claw 43, which will be described later, is in a state where seedlings can be planted in the field. The ascending position is a position where the elevating cylinder 32 sufficiently raises the planting portion 14 with respect to the vehicle body portion 11.

The planting unit 14 includes a planting input case unit 33, a plurality of planting units 34, a seedling stand 35, and a plurality of floats 36. The planting unit 14 can sequentially supply seedlings to each planting unit 34 from the seedling mounting table 35 and continuously plant the seedlings.

Each planting unit 34 has a planting transmission case portion 41 and a rotary case portion 42. Power is transmitted to the planting transmission case portion 41 via the PTO shaft 24 and the planting input case portion 33.

The rotary case portion 42 is rotatably attached to the planting transmission case portion 41. The rotating case portions 42 are arranged on both sides of the planting transmission case portion 41 in the vehicle width direction. Two planting claws 43 are attached to one side of each rotating case portion 42.

The two planting claws 43 are displaced as the rotating case portion 42 rotates. When the two planting claws 43 are displaced, one row of seedlings is planted.

The seedling stand 35 is arranged in front of and above the plurality of planting units 34. A seedling mat can be placed on the seedling stand 35. The seedling stand 35 can supply the seedlings of the seedling mat placed on the seedling stand 35 to each planting unit 34.

Specifically, the seedling stand 35 is configured to be laterally feedable (sliding in the lateral direction) so as to reciprocate in the vehicle width direction. Further, the seedling stand 35 is configured so that the seedling mat can be intermittently vertically fed downward at the reciprocating moving end of the seedling stand 35.

The float 36 is swingably provided at the lower part of the planting portion 14. In order to stabilize the planting posture of the planting portion 14 with respect to the field surface, the float 36 can bring the lower surface of the float 36 into contact with the field surface.

The float 36 is provided with a float sensor 37 that detects the posture of the float 36. The float sensor 37 can be configured as, for example, a potentiometer.

The spare seedling stand 38 is provided as a pair on the left and right with respect to the vehicle body portion 11. The spare seedling stand 38 is arranged outside the vehicle width direction of the bonnet 21. The spare seedling stand 38 can be equipped with a seedling box containing spare mat seedlings.

The upper parts of the left and right spare seedling stands 38 are connected to each other by a connecting frame 48 extending in the vertical direction and the vehicle width direction. A communication housing 49 is provided at the center of the connecting frame 48 in the vehicle width direction. Inside the communication housing 49, a positioning antenna 91 and a wireless communication antenna 92, which will be described later, are provided.

Subsequently, the drive transmission path in the rice transplanter 1 will be described with reference to FIG. FIG. 3 is a skeleton diagram showing the power transmission configuration of the rice transplanter 1.

As shown in FIG. 3, the driving force of the engine 22 is input to the mission case 23 via the drive transmission belt 50. A hydraulic mechanical continuously variable transmission (HMT) 51 is provided inside the transmission case 23, and the driving force of the engine 22 is continuously changed by the hydraulic mechanical continuously variable transmission 51. The gear ratio of the hydraulic mechanical continuously variable transmission 51 can be changed by the user operating the shift pedal 27.

The output of the hydraulic mechanical continuously variable transmission 51 is taken out from the transmission case 23 via the main clutch 52. The output of the hydraulic mechanical continuously variable transmission 51 is transmitted to the front wheels 12. Further, the output of the hydraulic mechanical continuously variable transmission 51 is transmitted to the rear wheels 13 via the propeller shaft 53. As a result, the front wheels 12 and the rear wheels 13 are driven.

A left side clutch 55L is provided in the drive transmission path from the propeller shaft 53 to the left rear axle 54L. Further, a right side clutch 55R is provided in the drive transmission path from the propeller shaft 53 to the right rear axle 54R.

The left and right side clutches 55L and 55R are configured so that they can be independently connected / disconnected by the control unit 30, respectively. That is, in the present embodiment, the rice transplanter 1 can individually switch whether or not the driving force is transmitted to the left and right rear wheels 13 and 13.

The left and right side clutches 55L and 55R are provided with left and right side clutch sensors, respectively. The detection results of the left and right side clutch sensors can be used to detect the connection / disconnection of the left and right side clutches 55L and 55R.

The output of the hydraulic mechanical continuously variable transmission 51 is taken out from the mission case 23 and transmitted to the PTO shaft 24 via the planting drive transmission shaft 61 and the planting speed change unit 62. The planting portion 14 is driven by the driving force of the PTO shaft 24.

The power of the PTO shaft 24 is input to the planting input case unit 33 of the planting unit 14. The driving force input to the planting input case unit 33 is transmitted to the drive shaft of the rotary case unit 42 via a plurality of transmission shafts, a plurality of transmission gears, and the like.

As described above, the rotary case portion 42 can be rotationally driven by the power of the engine 22. Therefore, seedlings can be planted by the planting unit 34 configured as a rotary planting device.

As shown in FIG. 3, the planted transmission unit 62 is provided with a transmission device including a plurality of gears. With this transmission, the speed at which the rotary case portion 42 of the planting portion 14 is rotationally driven can be changed. Thereby, the planting unit 14 can change the interval (distance between the seedlings) for planting the seedlings in the field.

The planting speed change unit 62 is provided with a planting clutch (working clutch) 63. By connecting the planting clutch 63, the planting portion 14 can be driven. By disengaging the planting clutch 63, the planting portion 14 can be driven and stopped.

The planting clutch 63 can be connected / disconnected by the control unit 30. Further, the planting clutch 63 can be switched between connection and disconnection by the user operating an operation member (planting clutch operation lever) (not shown).

The planting clutch 63 is provided with a planting clutch sensor 64. The detection result of the planting clutch sensor 64 can be used to detect the connection / disconnection of the planting clutch 63.

Next, the control unit 30 included in the rice transplanter 1 of the present embodiment will be described with reference to FIG. FIG. 4 is a functional block diagram of the rice transplanter 1 and the wireless communication terminal 3.

The control unit 30 is configured as a known computer, and includes a CPU, a ROM, a RAM, an input / output unit, and the like (not shown). The CPU can read various programs and the like from the ROM and execute them. Various programs and data are stored in the ROM. As shown in FIG. 4, the control unit 30 includes the automatic driving control unit 71, and can operate as the automatic driving control unit 71 by the cooperation of the hardware and software.

The control unit 30 is electrically connected to the sensor group 72. The sensor group 72 includes a pedal sensor 29, a float sensor 37, left and right side clutch sensors, and a planted clutch sensor 64. Further, the sensor group 72 includes a vehicle speed sensor 73, a work unit automatic control on / off switch 69, an operation detection switch of the auto cruise lever 68, and the like, which will be described later.

The control unit 30 can detect the operation position (depression amount) of the speed change pedal 27 based on the detection result of the pedal sensor 29. The control unit 30 can set the gear ratio of the hydraulic mechanical continuously variable transmission 51 according to the operation position of the shift pedal 27.

The control unit 30 can detect the elevating position of the planting unit 14 based on the detection result of the float sensor 37. For example, the control unit 30 can detect a change from the descending position of the planting unit 14 to the ascending position and a change from the ascending position to the descending position.

The control unit 30 can acquire the connection state / disconnection state of the left and right side clutches 55L and 55R from the detection results of the left and right side clutch sensors. As a result, the control unit 30 can detect the start / end of turning of the vehicle body unit 11 (rice transplanter 1).

The control unit 30 can acquire the connection state / disconnection state of the planting clutch 63 based on the detection result of the planting clutch sensor 64. As a result, the control unit 30 can detect the drive state / drive stop state.

The control unit 30 can acquire the vehicle speed and the mileage of the rice transplanter 1 from the detection result of the vehicle speed sensor 73. The vehicle speed sensor 73 is provided on the axle of the front wheel 12 so that the rotation of the axle can be detected. The vehicle speed sensor 73 may be provided at another appropriate position of the rice transplanter 1.

The control unit 30 is electrically connected to a plurality of controllers for controlling each configuration (for example, engine 22 and the like) included in the rice transplanter 1. In the present embodiment, the plurality of controllers include an engine controller 81, a vehicle speed controller (vehicle speed control unit) 82, a working unit controller 83, and a steering controller 84.

The engine controller 81 controls the rotation speed of the engine 22. The engine 22 is provided with a governor device 86 provided with an actuator (not shown) for changing the rotation speed of the engine 22. The engine controller 81 can control the governor device 86 based on the control signal input from the control unit 30 to control the rotation speed of the engine 22.

The vehicle speed controller 82 controls the vehicle speed of the rice transplanter 1. The vehicle speed controller 82 changes the angle of the movable swash plate of the hydraulic mechanical continuously variable transmission 51 based on the control signal input from the control unit 30 by the actuator shown in the figure, and the hydraulic mechanical continuously variable transmission 51 The gear ratio can be changed to achieve the vehicle speed desired by the user.

The vehicle speed control by the vehicle speed controller 82 includes auto cruise control (vehicle speed maintenance control). The auto cruise control is a control that causes the rice transplanter 1 to travel at a predetermined vehicle speed even when the foot is taken off from the speed change pedal 27.

The auto-cruise control is started by operating the auto-cruise lever 68 shown in FIG. 2 while the rice transplanter 1 is running. The auto cruise lever 68 can be operated on the ON side and the OFF side. The auto-cruise lever 68 is provided with a return spring (not shown), and when no operating force is applied to the auto-cruise lever 68, the auto-cruise lever 68 is in an intermediate position that is neither the ON side nor the OFF side. ..

The vehicle speed during auto-cruise control is set based on the operation position of the speed change pedal 27 when the auto-cruise lever 68 is operated to the ON side. Auto-cruise control can be terminated by operating the auto-cruise lever 68 to the OFF side. Further, the auto cruise control is automatically terminated by depressing the speed change pedal 27.

The working unit controller 83 controls the raising and lowering of the planting unit 14. The working unit controller 83 expands and contracts the elevating cylinder 32 based on the control signal input from the control unit 30, and appropriately elevates and retracts the planting unit 14. The working unit controller 83 can change the elevating position (height position) of the planting unit 14 to the descending position, the ascending position, or the like.

Further, the working unit controller 83 controls the left-right tilted posture of the planting unit 14. The working unit controller 83 can operate the tilting actuator 88 based on the control signal input from the control unit 30 to horizontally control the planting unit 14.

The steering controller 84 can control the steering angle of the front wheels 12. In the present embodiment, the steering controller 84 drives the steering actuator 87 based on the control signal input from the control unit 30, and controls the rotation angle of the steering handle 26 and the steering angle of the front wheels 12.

Specifically, a steering actuator 87 is provided in the middle of the steering shaft of the steering handle 26. In this configuration, when the rice transplanter 1 travels on a predetermined route, the control unit 30 calculates an appropriate rotation angle of the steering handle 26 so that the rice transplanter 1 travels along the route, and steers. A control signal is output to the controller 84. Then, the steering controller 84 changes the rotation angle of the steering handle 26 by the steering actuator 87 to control the steering angle of the front wheels 12.

Further, the steering controller 84 is configured to be able to control the rotation of the PTO shaft 24. The steering controller 84 switches the connection state / disconnection state of the planting clutch 63 of the planting speed change unit 62 based on the control signal input from the control unit 30. As a result, it is possible to control the transmission / cutoff of power to the PTO shaft 24 and drive or stop the planting portion 14.

The plurality of controllers such as the engine controller 81 described above control each unit such as the engine 22 based on the signal input from the control unit 30. Therefore, it can be said that the control unit 30 substantially controls each configuration included in the rice transplanter 1.

The control unit 30 is configured to be able to select whether or not to execute the work unit automatic control regarding the planting unit 14 by operating the work unit automatic control on / off switch 69. The automatic control of the working unit detects the start of turning of the rice transplanter 1 (the left and right side clutches 55L or 55R are disconnected), and automatically raises the planting unit 14 and disconnects the planting clutch 63. Detecting the end of turning of the rice transplanter 1 (shifting to the connected state of the side clutch 55L or 55R that was in the disconnected state), the planting portion 14 is lowered and the planting clutch 63 is automatically connected. .. As a result, it is possible to omit a series of operations when turning the vehicle between works, which enhances the convenience of the user.

The work unit automatic control on / off switch 69 can be alternately switched between the ON state and the OFF state by the operation of being pressed by the user with a finger. In the present embodiment, the work unit automatic control on / off switch 69 is provided in the vicinity of the steering handle 26 as shown in FIG.

The control unit 30 executes the work unit automatic control when the work unit automatic control on / off switch 69 is in the ON state. The control unit 30 does not execute the work unit automatic control when the work unit automatic control on / off switch 69 is in the OFF state.

In this way, the rice transplanter 1 provided with the control unit 30 as described above controls each part (planting unit 14 and the like) of the rice transplanter 1 by the control unit 30 when the user gets on the vehicle body unit 11 and performs various operations. Then, the planting work can be performed using the planting portion 14 while traveling in the field. In addition, the rice transplanter 1 can automatically travel and work based on a predetermined control signal output by the wireless communication terminal 3.

Specifically, as shown in FIG. 4, the rice transplanter 1 has various configurations for enabling automatic traveling. For example, the rice transplanter 1 has a configuration such as an automatic traveling control unit 71 of the control unit 30 and an antenna necessary for acquiring its own position information based on the positioning system. With such a configuration, the rice transplanter 1 can automatically travel in the field while acquiring its own position information by using the positioning system.

Next, the configuration for enabling the automatic traveling of the rice transplanter 1 will be described in detail. As shown in FIGS. 2 and 4, the rice transplanter 1 includes a positioning antenna 91, a wireless communication antenna 92, and a storage unit 93. In addition to these, the rice transplanter 1 may be provided with an inertial measurement unit (IMU) capable of acquiring the posture (roll angle, pitch angle, yaw angle) of the vehicle body portion 11.

The positioning antenna 91 can receive signals from positioning satellites constituting a positioning system such as a satellite positioning system (GNSS). The positioning signal received by the positioning antenna 91 is input to the position information calculation unit 95 shown in FIG. The position information calculation unit 95 calculates the position information of the rice transplanter 1 as, for example, latitude / longitude information. The position information calculated by the position information calculation unit 95 is input to the control unit 30 and used for the automatic travel of the rice transplanter 1 by the automatic travel control unit 71.

In this embodiment, a high-precision satellite positioning system using the GNSS-RTK method is used as the positioning system, but the present invention is not limited to this, and other positioning can be obtained as long as high-precision position coordinates can be obtained. A system may be used. For example, it is conceivable to use a relative positioning method (DGPS) or a geostationary satellite type satellite navigation augmentation system (SBAS) as the positioning system.

The wireless communication antenna 92 can receive a signal from the wireless communication terminal 3 operated by the user and can transmit a signal to the wireless communication terminal 3. The signal from the wireless communication terminal 3 received by the wireless communication antenna 92 is signal-processed by the wireless communication unit 96 shown in FIG. 4 and then input to the control unit 30. Further, the signal transmitted from the control unit 30 to the wireless communication terminal 3 is signal-processed by the wireless communication unit 96, then transmitted from the wireless communication antenna 92 and received by the wireless communication terminal 3.

The storage unit 93 stores the travel route (path) in which the rice transplanter 1 is automatically traveld among the routes traveled by the rice transplanter 1, and records the transition (travel locus) of the position of the rice transplanter 1 during travel. You can memorize it. In addition, the storage unit 93 stores various information necessary for the rice transplanter 1 to automatically travel and work automatically. The storage unit 93 is composed of, for example, a flash memory or a non-volatile memory such as a hard disk.

The wireless communication terminal 3 is configured as a computer that can be carried by a user, for example, a tablet-type personal computer. The user can confirm the information about the rice transplanter 1 and the like by referring to the information displayed on the display unit (display) 101 of the wireless communication terminal 3. Further, the user operates the operation unit of the wireless communication terminal 3 (for example, the touch panel provided on the display unit 101) to transmit a control signal for controlling the rice transplanter 1 to the control unit 30 of the rice transplanter 1. can do. As the control signal, for example, a signal instructing the start or end of the automatic traveling of the rice transplanter 1 can be considered.

The rice transplanter 1 configured in this way is controlled based on the instruction of the user who uses the wireless communication terminal 3, and automatically travels along the traveling route of the field while planting work using the planting unit 14. It can be performed.

Next, the configuration of the wireless communication terminal 3 will be described with reference to FIG.

As shown in FIG. 4, the wireless communication terminal 3 includes a communication unit 122, an automatic driving operation unit 123, a control unit 124, and a route generation unit 125, in addition to the display unit 101 described above.

The communication unit 122 is configured as, for example, a wireless communication module. The communication unit 122 is electrically connected to the communication antenna 127. The communication antenna 127 has a short-range communication antenna for wireless communication with the rice transplanter 1 and a mobile communication antenna for communication using a mobile phone line and the Internet. The communication unit 122 can perform modulation processing or demodulation processing by an appropriate method to transmit / receive data to / from the rice transplanter 1 or another device.

The automatic traveling operation unit 123 is configured as, for example, a touch panel, and is included in the operation unit of the wireless communication terminal 3 described above. The automatic traveling operation unit 123 can instruct the automatic traveling control unit 71 (control unit 30) of the rice transplanter 1 to start and end the automatic traveling.

The wireless communication terminal 3 is configured as a known computer, and includes a CPU, a ROM, a RAM, an input / output unit, and the like (not shown). The CPU can read various programs and the like from the ROM and execute them. Further, various programs and data are stored in the ROM. Then, by the cooperation of the software and the hardware described above, the wireless communication terminal 3 can be operated as the control unit 124, the route generation unit 125, and the like.

The control unit 124 can transmit the information of the automatic traveling route generated by the route generation unit 125 to the rice transplanter 1 by communicating with the control unit 30 of the rice transplanter 1 by the communication unit 122. Further, the control unit 124 can transmit a command from the automatic driving operation unit 123 to the automatic driving control unit 71 in the rice transplanter 1 via the communication unit 122. Further, when the rice transplanter 1 is automatically traveling, the control unit 124 can receive the state (position, vehicle speed, etc.) of the rice transplanter 1 from the rice transplanter 1 and display it on the display unit 101.

The route generation unit 125 can generate a travel route (automatic travel route) on which the rice transplanter 1 automatically travels based on field information, aircraft information, and the like. The field information includes information on the shape of the field, information on the automatic driving start position, and information on the automatic driving direction. The information on the shape of the field is specified based on the movement locus at that time, for example, before the rice transplanter 1 starts automatic running, the user manually operates the rice transplanter 1 to run along the outer circumference of the field. To. Hereinafter, the above-mentioned running may be referred to as a field shape-specific running. The information on the automatic traveling start position and the information on the automatic traveling direction are specified by the user when the automatic traveling route is generated by using the wireless communication terminal 3. The method of designation is not particularly limited, but as the automatic running start position, for example, the user may specify an arbitrary position on the locus while the display unit 101 displays the movement locus of the field shape specific running. can. Further, as the automatic traveling direction, the user can specify any two points in the movement locus of the field shape specifying traveling displayed on the display unit 101, and can be designated as the direction of a straight line connecting the two points.

The aircraft information includes, for example, the front-rear vehicle length and left-right vehicle width of the entire rice transplanter 1 including the vehicle body portion 11 and the planting portion 14, the distance from the positioning antenna 91 in the positioning system to the work center of the planting portion 14, and the rice transplanter. Information such as the turning radius of the machine 1 and information indicating the maximum number of planting rows by the planting unit 14 are included. Then, the automatic traveling route generated by the route generation unit 125 of the wireless communication terminal 3 is input (transferred) to the storage unit 93 of the rice transplanter 1. At this time, information on the positional relationship between the positioning antenna 91 and the work center of the planting unit 14 is also transmitted from the wireless communication terminal 3 to the rice transplanter 1. As a result, the control unit 30 (automatic traveling control unit 71) of the rice transplanter 1 can grasp the work center position of the planting unit 14.

FIG. 5 shows an example of an automatic traveling route generated by the route generation unit 125. As shown in FIG. 5, the field 130 can be considered separately as a central region 131 and an outer peripheral region 132 surrounding the periphery of the central region 131. The width of the outer peripheral region 132 is determined based on the above-mentioned field information and aircraft information.

In the central region 131 of the field 130, a reciprocating route for planting work is generated by the planting portion 14. The round-trip route has a plurality of working routes 136. Each work route 136 extends linearly so that the rice transplanter 1 travels straight.

In the outer peripheral region 132 of the field 130, a turning path 137 connecting one end point (end end) E1 of the adjacent work paths 136 and the other start point (start end) S1 among the plurality of work paths 136 is generated. Will be done.

As described above, the automatic traveling path generated by the route generation unit 125 has a plurality of work paths 136 and a plurality of turning paths 137, and the appropriate working paths 136 and turning paths 137 are alternately connected. It has become.

Next, the processing when the rice transplanter 1 performs automatic traveling will be described with reference to FIGS. 6 to 10. FIG. 6 is a flowchart showing a process of determining whether or not to execute the work unit automatic control. FIG. 7 is a flowchart of the work unit automatic control. FIG. 8 is a diagram showing a part of the automatic traveling route. FIG. 9 is a flowchart showing a process of determining whether or not to execute the auto cruise control. FIG. 10 is a flowchart of vehicle speed control including auto cruise control.

In the present embodiment, the rice transplanter 1 starts automatic traveling by instructing the rice transplanter 1 to start automatic traveling by the wireless communication terminal 3.

However, the automatic driving control unit 71 determines whether or not a predetermined automatic driving start condition is satisfied before actually starting the automatic driving. This automatic driving start condition is satisfied when all of the following conditions are satisfied.
(1) The path search is completed (2) The steering angle is within the predetermined range with respect to the working direction of the rice transplanter 1 (3) The traveling part of the rice transplanter 1 is neutral (neutral) ( 4) The parking brake of the rice transplanter 1 is OFF (5) The steering operation flag is OFF (6) The speed fixing flag is OFF (7) No abnormality related to automatic planting has occurred. , This is an example, and some conditions may be omitted or other conditions may be added.

Here, "the path search is completed" means that the rice transplanter 1 has specified any work route 136 among the plurality of work routes 136 as the automatic traveling start target route. For example, the rice transplanter 1 specifies the work route 136 to which the start point S1 closest to the position of the rice transplanter 1 belongs among the start points S1 of each work route 136 as the automatic traveling start target route.

"The traveling portion of the rice transplanter 1 is neutral" means that the main clutch 52 shown in FIG. 3 is disengaged. For example, in the rice transplanter 1, when the main shift lever (not shown) is operated by the user to the neutral position, the main clutch 52 is disengaged and the traveling portion of the rice transplanter 1 becomes neutral.

"The steering operation flag is OFF" means that the steering handle 26 is not manually operated by the user. The steering operation flag is data stored in the control unit 30, and indicates whether or not the steering handle 26 is artificially operated. When the steering operation flag is ON, it means that the steering handle 26 is artificially operated, and when the steering operation flag is OFF, it means that the steering handle 26 is not artificially operated. The state of the steering operation flag is updated at any time.

"The speed fixing flag is OFF" means that the above-mentioned auto cruise control is not executed. The speed fixing flag is data stored in the control unit 30, and indicates whether or not the auto cruise control is executed. When the speed fixing flag is ON, it means that the auto cruise control is executed, and when the speed fixing flag is OFF, it means that the auto cruise control is not executed. The state of the fixed speed flag is changed at any time as described later.

"No abnormality related to automatic planting" means that there is no abnormality that hinders the raising and lowering of the planting unit 14 and the connection / disconnection of the planting clutch 63 of the planting speed change unit 62. Means that. When the elevating cylinder 32 fails, the planting clutch 63 fails, or the like, the automatic traveling of the rice transplanter 1 is not permitted. Even if an abnormality related to the horizontal control of the planting unit 14 by the working unit controller 83 occurs, the planting unit 14 can be leveled by the spring mechanism provided in the rice transplanter 1. In this case, , Automatic running of rice transplanter 1 is permitted (it is treated as if there is no abnormality related to automatic planting).

When the automatic traveling control unit 71 determines that the above automatic traveling start conditions are satisfied, the rice transplanter 1 causes the rice transplanter 1 to start automatic traveling. After the automatic traveling of the rice transplanter 1 is started, the automatic traveling control unit 71 causes the rice transplanter 1 to automatically travel along the traveling route generated by the route generation unit 125.

The automatic driving control unit 71 turns on the automatic traveling flag when the rice transplanter 1 starts automatic traveling. The automatic traveling flag is data stored in the control unit 30, and indicates whether or not the rice transplanter 1 is in automatic traveling. When the automatic driving flag is ON, it means that the rice transplanter 1 is in automatic driving, and when it is OFF, it means that it is not in automatic driving.

In the automatic driving control by the automatic driving control unit 71, the automatic driving control unit 71 outputs a control signal to the steering controller 84 so that the rice planting machine 1 travels along the automatic driving path 135, and the steering controller 84 sends the control signal to the control signal. It is executed by controlling the steering angle based on.

While the automatic driving control is being executed, the vehicle speed of the rice transplanter 1 is in principle instructed by the manual operation of the user. Specifically, the vehicle speed during automatic traveling of the rice transplanter 1 is controlled by the vehicle speed controller 82 based on the operation of the speed change pedal 27.

The automatic driving control unit 71 monitors whether or not a predetermined automatic driving end condition is satisfied during automatic driving. Various conditions for ending automatic driving can be considered. For example, it is conceivable that the rice transplanter 1 is instructed to end automatic driving by the wireless communication terminal 3. Further, even when it becomes undesired to continue the automatic driving, such as when the steering operation flag is turned on or when the rice transplanter 1 deviates from the automatic traveling path 135 by a predetermined deviation or more, the automatic traveling end condition is set. To establish.

When the automatic traveling control unit 71 determines that the above-mentioned automatic traveling end condition is satisfied, the automatic traveling control unit 71 terminates the automatic traveling of the rice transplanter 1. The method of ending automatic driving differs depending on the situation. For example, when the running of the rice transplanter 1 should be stopped immediately, such as when the communication of the wireless communication terminal 3 is cut off or the obstacle sensor in the figure is used to detect an obstacle, the automatic running control unit 71 immediately stops the engine 22. After controlling so as to end the automatic driving. On the other hand, when the user gives an instruction to end the automatic driving, the automatic driving control unit 71 performs deceleration control for smoothly decelerating so that the vehicle speed becomes zero by the vehicle speed controller 82, and then ends the automatic driving. do. The automatic running control unit 71 turns off the automatic running flag after finishing the automatic running of the rice transplanter 1.

Next, the automatic control of the working unit will be described.

As described above, the work unit automatic control is a series of controls relating to the planting unit 14 when the rice transplanter 1 is swiveled between operations. Whether or not to perform this automatic work unit control is determined according to the state of the automatic work unit control flag, which is data stored in the control unit 30. If the work unit automatic control flag is ON, the work unit automatic control is performed, and if it is OFF, the work unit automatic control is not performed.

As a general rule, the state of the work unit automatic control flag can be switched by the user operating the work unit automatic control on / off switch 69 to turn it into an ON state or an OFF state. However, the automatic traveling control unit 71 forcibly changes the working unit automatic control flag to ON during the automatic traveling of the rice transplanter 1 even when the working unit automatic control on / off switch 69 is in the OFF state. That is, during the automatic traveling of the rice transplanter 1, the automatic control of the working unit is executed regardless of whether the automatic control on / off switch 69 of the working unit is in the ON state or the OFF state.

Further, even if the work unit automatic control on / off switch 69 is turned on and the work unit automatic control on / off switch 69 is switched to the OFF state after the automatic running of the rice transplanter 1 is started, the work unit is automatic. The control flag remains ON.

Specific processing will be described with reference to the flowchart of FIG. When the process of FIG. 6 is started, the automatic traveling control unit 71 determines whether or not the rice transplanter 1 is currently in automatic traveling (step S101). This determination can be made based on the above-mentioned automatic driving flag. When the rice transplanter 1 is in automatic traveling, the automatic traveling control unit 71 sets the working unit automatic control flag to ON (step S102). After that, the process returns to step S101.

If it is determined in step S101 that the vehicle is not in automatic driving, the automatic driving control unit 71 determines whether or not the working unit automatic control on / off switch is in the ON state (step S103). If it is in the ON state, the automatic travel control unit 71 sets the work unit automatic control flag to ON (step S102). If not, the automatic traveling control unit 71 sets the working unit automatic control flag to OFF (step S104). In either case, the process returns to step S101.

Next, the actual automatic control of the working unit will be described with reference to the flowchart of FIG. 7.

The process of FIG. 7 is executed in parallel with the process of FIG. When the process of FIG. 7 is started, the control unit 30 determines whether or not the work unit automatic control flag is ON (step S201). If the work unit automatic control flag is OFF, the process returns to step S201 (therefore, the processes of steps S202 to S205 are not performed).

If the work unit automatic control flag is ON in the determination of step S201, the control unit 30 determines whether or not the rice transplanter 1 has started turning (step S202). There are various methods for determining this, but for example, when one of the side clutches 55L and 55R provided on the left and right rear wheels 13 and 13 is disengaged, it is conceivable that it is determined that the turning has started. According to this determination method, the point where the start of turning is detected is generally the point Q1 in FIG.

When the rice transplanter 1 starts turning at the judgment of step S202, the control unit 30 raises the planting unit 14 to the ascending position by the working unit controller 83, and disengages the planting clutch 63 by the steering controller 84. The state is set (step S203). The timing of raising the planting portion 14 and disconnecting the planting clutch 63 can be changed as appropriate. If the rice transplanter 1 has not started turning at the judgment of step S202, the process of step S203 is skipped.

Subsequently, the control unit 30 determines whether or not the rice transplanter 1 has completed turning (step S204). There are various methods for determining this, but for example, when the mileage during turning exceeds a predetermined distance and one of the side clutches 55L and 55R that has been disengaged is reconnected, the turning is completed. It is conceivable to judge. According to this determination method, the point where the end of turning is detected is generally the point Q2 in FIG.

When the rice transplanter 1 finishes turning at the judgment of step S204, the control unit 30 lowers the planting unit 14 to the descending position by the working unit controller 83, and connects the planting clutch 63 by the steering controller 84. The state is set (step S204). The timing between the lowering of the planting portion 14 and the connection of the planting clutch 63 can be changed as appropriate. If the rice transplanter 1 has not completed the turn at the judgment of step S204, the process of step S205 is skipped. After that, the process returns to step S201.

Next, vehicle speed control including auto cruise control will be described.

As described above, the auto cruise control is a vehicle speed at a speed corresponding to the operation position of the shift pedal 27 when the auto cruise lever 68 is operated to the ON side in the past even if the operating force is not applied to the shift pedal 27. The controller 82 is a control for maintaining the running of the rice transplanter 1. Whether or not to perform this auto-cruise control is determined according to the state of the speed fixing flag which is the storage content of the control unit 30. If the speed fixing flag is ON, auto-cruise control is performed, and if it is OFF, auto-cruise control is not performed.

In principle, the speed fixing flag can be turned ON / OFF by the user operating the auto cruise lever 68 to the ON side or the OFF side. However, even if the speed fixing flag is ON, the automatic traveling control unit 71 sets the speed fixing flag under predetermined conditions such as when traveling on the turning path 137 during the automatic traveling of the rice transplanter 1. Forcibly change to OFF. Therefore, when the rice transplanter 1 is automatically traveling on the turning path 137 shown in FIG. 8, the auto cruise control is prohibited. When the rice transplanter 1 is automatically traveling, the auto-cruise control is permitted only when the rice transplanter 1 is traveling on the work route 136.

Strictly speaking, considering the case where the rice transplanter 1 automatically travels on the work route 136 on the left side of FIG. 8, the section where the automatic travel control unit 71 permits the execution of the auto cruise control is the work route 136. It is not the entire section from the start point S1 to the end point E1. The section where auto-cruise control is permitted is from the start point S1 of the work route 136 to a point in the middle near the end point E1 (a predetermined point before the end point E1 by a predetermined distance) P1. The point P1 on the way and the end point E1 are separated by a predetermined distance (first predetermined distance L1).

Execution of auto-cruise control is prohibited in the section from the intermediate point P1 to the end point E1 in the work route 136. Further, the execution of the auto cruise control is prohibited even in the entire section of the turning path 137. In this way, in the section immediately before turning and the section where turning is performed, the vehicle speed is controlled according to the operation position of the speed change pedal 27. Therefore, it is possible to perform agile and careful shift operation at the discretion of the user.

However, of the work path 136 and the turning path 137 constituting the automatic traveling path 135, a predetermined upper limit value is set for the vehicle speed based on the operation amount of the speed change pedal 27 during automatic traveling during automatic traveling on the turning path 137. There is. Therefore, the rice transplanter 1 cannot automatically travel on the turning path 137 at a vehicle speed exceeding the upper limit vehicle speed regardless of the operation amount of the speed change pedal 27. As a result, the vehicle speed of the rice transplanter 1 is limited to the upper limit vehicle speed or less, so that a stable ride quality when turning can be realized.

Further, in the present embodiment, the check control is performed with respect to the vehicle speed when the rice transplanter 1 shifts from the turning path 137 to the working path 136 during automatic traveling.

For example, consider a case where the user depresses the speed change pedal 27 to the maximum while the rice transplanter 1 is traveling on the turning path 137. With the above control, the vehicle speed of the rice transplanter 1 traveling on the turning path 137 becomes a predetermined upper limit value. After that, consider a case where the rice transplanter 1 shifts to the work path 136 while the user maintains the operation position of the speed change pedal 27. At this time, if the upper limit of the vehicle speed is released, the rice transplanter 1 may accelerate against the intention of the user.

In consideration of the above, in the present embodiment, even if the rice transplanter 1 during automatic traveling finishes traveling on the turning path 137 and starts traveling on the work path 136, the user decelerates the operation amount of the speed change pedal 27 by a predetermined amount. Unless it is operated to the side, the control of the upper limit of the vehicle speed performed on the turning path 137 is maintained (check control). As a result, acceleration is performed based on an explicit operation in which the user depresses the shift pedal 27 and depresses it again, so that the user's sense of security can be enhanced.

Specific processing will be described with reference to the flowchart of FIG. When the process of FIG. 9 is started, the control unit 30 determines whether or not the rice transplanter 1 is currently running automatically (step S301).

When the rice transplanter 1 is not automatically traveling, the control unit 30 determines whether or not the auto cruise lever 68 has been operated to the OFF side (step S302). When the auto cruise lever 68 is operated to the OFF side, the control unit 30 changes the speed fixing flag to OFF when the speed fixing flag is ON (step S303). After that, the process returns to step S301.

In step S302 described above, in reality, not only the operation of the auto cruise lever 68 to the OFF side but also other operations for automatically ending the auto cruise control (specifically, depressing the speed change pedal 27) are performed. It is also determined whether or not it has been done. Even if the auto cruise lever 68 is not operated to the OFF side, if the speed change pedal 27 is depressed, the speed fixing flag is changed from ON to OFF in step S303.

If the auto-cruise lever 68 is not operated to the OFF side in the determination of step S302, the control unit 30 determines whether or not the auto-cruise lever 68 is conversely operated to the ON side (step S304). When the auto cruise lever 68 is operated to the ON side, the control unit 30 changes the speed fixing flag to ON when the speed fixing flag is OFF (step S305). If the auto cruise lever 68 is not operated to the ON side, the process of step S305 is skipped. After that, the process returns to step S301.

If the rice transplanter 1 is in automatic traveling by the judgment of step S301, the automatic traveling control unit 71 determines whether or not the rice transplanter 1 is on the work path 136 (step S306). This determination can be made based on the work center position of the planting unit 14 calculated from the current position of the rice transplanter 1. When the rice transplanter 1 is not in the work path 136 (that is, in the turning path 137), the automatic traveling control unit 71 turns off the speed fixing flag if it is ON (step S303). After that, the process returns to step S301.

In the determination of step S306, when the rice transplanter 1 is on the work path 136, the automatic traveling control unit 71 determines whether or not the rice transplanter 1 is in front of the above-mentioned intermediate point P1 on the work path 136. (Step S307). This determination can be made based on the work center position of the planting portion 14 in the same manner as described above. When the rice transplanter 1 is not in front of the point P1 in the middle (that is, the rice transplanter 1 is traveling beyond the point P1), the automatic traveling control unit 71 turns off the speed fixing flag if it is ON (step S303). ). After that, the process returns to step S301.

As shown in the flowchart of FIG. 9, when the rice transplanter 1 is automatically traveling on the turning path 137, or when the rice transplanter 1 is automatically traveling on the side closer to the end point than the point P1 in the middle of the work path 136, the speed is The fixed flag is turned off. Further, in the above case, the operation of the auto cruise lever 68 toward the ON side is invalidated. As a result, the prohibition of auto cruise control is realized.

Although omitted in FIG. 9, even when the user operates the wireless communication terminal 3 to instruct the end of automatic driving, the speed fixing flag is changed to OFF when the speed fixing flag is ON. As a result, the auto cruise control will be automatically canceled.

Next, the actual vehicle speed control will be described with reference to the flowchart of FIG.

The process of FIG. 10 is executed in parallel with the process of FIG. When the process of FIG. 10 is started, the control unit 30 determines whether or not the speed fixing flag is ON (step S401).

When the speed fixing flag is ON, the control unit 30 sets the target vehicle speed based on the operation amount of the speed change pedal 27 at the time when the auto cruise lever 68 is operated to the ON side (step S402). Subsequently, the control unit 30 (vehicle speed controller 82) controls the vehicle speed of the rice transplanter 1 so as to approach the target vehicle speed (step S403). After that, the process returns to step S401.

If the speed fixing flag is OFF at the judgment of step S401, the control unit 30 sets the target vehicle speed based on the current operation amount of the speed change pedal 27 (step S404).

After that, the control unit 30 determines whether or not the rice transplanter 1 is currently running automatically (step S405). When the rice transplanter 1 is on the turning path 137 and the target vehicle speed set in step S404 exceeds the upper limit value, the automatic driving control unit 71 sets the target vehicle speed as the upper limit value. (Step S406). This makes it possible to prevent turning at an excessive speed during automatic driving. Further, the automatic driving control unit 71 does not release the depressing of the speed change pedal 27 after the rice transplanter 1 shifts from the turning path 137 to the working path 136, and the target vehicle speed set in step S404 is the upper limit value. If it exceeds, the target vehicle speed is changed so as to be the upper limit (step S407). As a result, the above-mentioned check control is realized. If it is determined in step S405 that the rice transplanter 1 is not currently in automatic traveling, the processes of steps S406 and S407 are skipped.

Subsequently, the control unit 30 controls the vehicle speed of the rice transplanter 1 so as to approach the target vehicle speed (step S403). After that, the process returns to step S401.

Next, the notification control will be described.

In the present embodiment, when the position of the rice transplanter 1 (the work center position of the planting portion 14) reaches the point R1 slightly before the end point E1 of the work path 136 during automatic traveling, the turning path 137 is used. A notification is given to notify that the vehicle is about to shift to driving. The notification can be performed by, for example, a display on a lamp or a sound. The notification to the user may be performed on the rice transplanter 1 side or on the wireless communication terminal 3 side. As a result, the user can know that the traveling direction of the rice transplanter 1 will be changed soon, so that he / she prepares by sitting deeply in the driver's seat 25 against the shaking caused by the turning of the rice transplanter 1. Can be left. Since this notification control can be realized by a simple process of monitoring the current position of the rice transplanter 1, the flowchart is omitted.

Next, an example will be described of how the rice transplanter 1 operates during automatic traveling by the above control.

After getting on the stopped rice transplanter 1, the user operates the wireless communication terminal 3 to instruct the start of automatic driving. In this explanation, when the start of automatic running is instructed, the work unit automatic control on / off switch 69 of the rice transplanter 1 is in the OFF state. Further, the depressing of the speed change pedal 27 has been released, and the auto-cruise control by the auto-cruise lever 68 has not been turned on.

Based on the above instructions, the automatic running of the rice transplanter 1 is started. Since the speed fixing flag is initially turned off, the substantial movement of the rice transplanter 1 is started when the user depresses the speed change pedal 27.

By the way, the position of the rice transplanter 1 (strictly speaking, the position of the work center of the planting unit 14) when the user instructs the start of automatic driving and the position of the starting point of the above-mentioned automatic driving start target route are one. Not always done. Therefore, before the traveling along the above-mentioned automatic traveling route 135 is performed, the automatic traveling control unit 71 plans to start the automatic traveling along the automatic traveling route 135 at the position of the work center of the planting unit 14. The rice transplanter 1 is driven by automatic steering so as to coincide with the point (preliminary driving).

Here, assuming that automatic driving can be started while traveling under auto-cruise control, for example, the rice transplanter 1 may turn at high speed and change course at the moment when the user instructs to start automatic driving. There is. However, in the present embodiment, as described above, the automatic driving by the automatic driving control unit 71 is not started unless the automatic cruise control by the vehicle speed controller 82 is released. Therefore, the vehicle speed of the rice transplanter 1 in the above-mentioned pre-traveling always follows the operation of the speed change pedal 27 of the user. As a result, the user can instruct the start of automatic driving with peace of mind.

After the rice transplanter 1 has moved to a predetermined position by the pre-traveling, the rice transplanter 1 travels according to the automatic traveling route 135 shown in FIG. Specifically, the automatic traveling control unit 71 automatically steers so as to realize traveling along the automatic traveling path 135. The vehicle speed of the rice transplanter 1 at this time is controlled so as to be a vehicle speed according to the amount of depression of the speed change pedal 27 by the user. When the rice transplanter 1 is traveling on the work path 136, the planting portion 14 is in the lowered position and the planting clutch 63 is connected, so that the seedling planting work is performed.

Consider, for example, a case where the rice transplanter 1 is in the position shown in FIG. 8, and the user depresses the speed change pedal 27 by a desired amount and operates the auto cruise lever 68 to the ON side. In this case, the speed fixing flag is changed from OFF to ON. After that, even if the user releases the operating force on the speed change pedal 27, the vehicle speed controller 82 controls the traveling speed of the rice transplanter 1 so as to maintain the vehicle speed at the time when the auto cruise lever 68 is operated to the ON side. (Auto cruise control).

After that, when the rice transplanter 1 traveling on the work route 136 approaches a predetermined point P1 in the middle, the auto cruise control is prohibited, so that the speed fixing flag is automatically changed from ON to OFF. As a result, the vehicle speed of the rice transplanter 1 is controlled so as to be a vehicle speed according to the current depression amount of the speed change pedal 27. During the auto cruise control, the user does not depress the speed change pedal 27. Therefore, when the speed fixing flag is changed from ON to OFF, the vehicle speed controller 82 controls the rice transplanter 1 to start deceleration from the above point P1. When the state in which the speed change pedal 27 is not depressed is maintained, the rice transplanter 1 stops at a point slightly advanced from the point P1 (for example, the point R1). The position of the stop point changes according to the vehicle speed at the time of auto cruise control, but auto cruise control is performed so that the stop point is before the end point E1 of the work route 136 even if the auto cruise control is performed at the maximum vehicle speed. The position of the point P1 where is prohibited is set.

After that, the user depresses the speed change pedal 27 by a desired amount. As a result, the rice transplanter 1 starts running again. Immediately, the rice transplanter 1 shifts from the working path 136 to the turning path 137.

The work unit automatic control on / off switch 69 is in the OFF state as described above, but the work unit automatic control flag is forcibly turned on during automatic driving. Therefore, in the turning path 137, the working unit is automatically controlled. Specifically, when the rice transplanter 1 reaches the point Q1 where the side clutch 55R on the inside of the turn is in the disengaged state, the planting portion 14 rises to the ascending position and the planting clutch 63 is in the disengaged state. After that, when the rice transplanter 1 reaches the point Q2 where the side clutch on the inside of the turn (side clutch 55R in the case of FIG. 8) is connected, the rice transplanter 1 descends to the descending position and the planting clutch 63 moves. It will be connected.

When the user desires the automatic traveling of the rice transplanter 1 along the automatic traveling path 135, usually, the raising / lowering control of the planting portion 14 and the disconnection / disconnection control of the planting clutch 63 at the time of turning between works are performed. It is thought that they also hope for this. Therefore, even when the work unit automatic control on / off switch 69 is in the OFF state, the work unit automatic control can reduce the time and effort of the user.

However, for some reason, the user may wish to switch from automatic driving to manual driving on the way. In this case, for example, the user manually operates the steering wheel 26 to automatically cancel the automatic driving. Along with this, the compulsion of turning on the work unit automatic control flag is released. After that, the state of the work unit automatic control flag follows the state of the work unit automatic control on / off switch 69 operated by the user. Therefore, after the automatic driving is canceled, the user's intention can be surely reflected regarding whether or not to execute the automatic control of the working unit.

When the rice transplanter 1 is traveling on the turning path 137, auto cruise control is prohibited. Therefore, even if the user operates the auto-cruise lever 68 to the ON side, the auto-cruise control is not performed on the turning path 137. As a result, the vehicle speed of the rice transplanter 1 is controlled based on the amount in which the user actually depresses the speed change pedal 27 during the automatic traveling on the turning path 137. Further, even if the user depresses the speed change pedal 27 greatly, the rice transplanter 1 does not turn at an excessive speed due to the above-mentioned upper limit control of the vehicle speed.

After that, the rice transplanter 1 shifts to the work path 136. When the rice transplanter 1 enters the work path 136 from the turning path 137 at a speed higher than a predetermined speed, the upper limit control of the vehicle speed is not released even in the work path 136 unless the user depresses the speed change pedal 27 to some extent (described above). Check control). In order to release the check control, the user depresses the speed change pedal 27 once and then depresses it again. As a result, the rice transplanter 1 can be driven at a speed higher than the above-mentioned upper limit speed on the work path 136. Since the auto-cruise control is permitted again in the work path 136, the user can start the auto-cruise control by the auto-cruise lever 68 in the same manner as described above.

It should be noted that the notification control for notifying the end of the auto-cruise control may be performed at the point P2 before the end of the auto-cruise control at the above-mentioned intermediate point P1. The point P1 at which the auto-cruise control ends and the point P2 at which the notice is given are separated by an appropriate distance (second predetermined distance L2). Upon receiving this notice, the user can quickly end the auto-cruise control (specifically, depress the speed change pedal 27) to shift from the work path 136 to the turn path 137 without stopping the rice transplanter 1. .. As a result, the work by automatic running can be smoothly performed. When the rice transplanter 1 enters the turning path 137 from the working path 136 without stopping, the above-mentioned notification control for notifying the fact immediately before the transition to the turning path 137 is more preferable.

As described above, the automatic traveling system of the rice transplanter 1 of the present embodiment includes an automatic traveling control unit 71. The automatic traveling control unit 71 uses a positioning system to connect a plurality of work paths 136 in which the planting work is performed by the planting unit 14 and a turning path 137 connecting adjacent work paths 136 among the plurality of work paths. It is possible to automatically drive the rice transplanter 1 along the automatic traveling path 135 having the above. The rice transplanter 1 includes a vehicle speed controller 82 that controls the vehicle speed of the rice transplanter 1 and a speed change pedal 27 that operates the vehicle speed of the rice transplanter 1. The vehicle speed controller 82 can execute auto-cruise control for maintaining the vehicle speed of the rice transplanter 1 corresponding to the operating position of the speed change pedal 27 before the release even if the operating force on the speed change pedal 27 is released. The automatic driving control unit 71 permits the automatic cruise control by the vehicle speed controller 82 when the rice transplanter 1 is automatically driven along the work path 136, while the rice transplanter 1 is automatically driven along the turning path 137. If so, auto-cruise control by the vehicle speed controller 82 is prohibited.

As a result, when the rice transplanter 1 automatically travels on the turning path 137, the execution of the auto cruise control is prohibited, so that the user himself / herself determines the vehicle speed appropriately when the rice transplanter 1 turns. Therefore, the cautiousness of turning can be ensured. Further, since the rice transplanter 1 generally does not perform the planting work when traveling along the turning path, it is possible to prevent deterioration of workability.

Further, in the automatic traveling system of the rice transplanter 1 of the present embodiment, the automatic traveling control unit 71 is from the end point E1 of the working path 136 even when the rice transplanter 1 is automatically traveling along the working path 136. Also prohibits auto-cruise control by the vehicle speed controller 82 in the section from the point P1 before the first predetermined distance L1 to the end point E1.

When the rice transplanter 1 is traveling along the work path 136, the auto-cruise control is prohibited from the point P1 where the remaining distance to the turn path 137 is shortened, so that the stage before reaching the turn path 137 The user will manually determine the vehicle speed. Therefore, the user's sense of security when the rice transplanter 1 turns on the turning path 137 is improved.

Further, in the automatic traveling system of the rice transplanter 1 of the present embodiment, the automatic traveling control unit 71 automatically causes the rice transplanter 1 to travel along the work path 136 while the auto cruise control by the vehicle speed controller 82 is being executed. When the position of the rice transplanter 1 reaches the above-mentioned point P1, the vehicle speed controller 82 is controlled to decelerate the rice transplanter 1 and then stop the rice transplanter 1.

When the rice transplanter 1 that automatically travels reaches a predetermined point P1, the auto cruise control is canceled. By controlling the deceleration of the rice transplanter 1 at this time, for example, it is possible to avoid a sudden stop and improve the riding comfort.

Further, in the automatic traveling system of the rice transplanter 1 of the present embodiment, the automatic traveling control unit 71 causes the rice transplanter 1 to start automatic traveling along the work route 136 when the automatic traveling start condition is satisfied. Is possible. The automatic traveling start condition includes that the automatic cruise control is not executed by the vehicle speed controller 82.

If the automatic driving start during the execution of the auto cruise control is permitted, the rice transplanter 1 may be dependent on the positional relationship between the point where the automatic driving is scheduled to start along the automatic traveling route 135 and the current position of the rice transplanter 1. May change course at high speed. By prohibiting the automatic start of traveling during the execution of the auto cruise control, the rice transplanter 1 can be moved to the above-mentioned planned point while surely following the instruction of the vehicle speed by the user.

Further, the automatic traveling system of the rice transplanter 1 of the present embodiment includes an automatic traveling operation unit 123. The automatic running operation unit 123 issues a start command and an end command for automatic running of the rice transplanter 1 to the automatic running control unit 71. The automatic driving control unit 71 automatically operates the automatic driving operation unit 123 while the rice transplanter 1 is automatically traveling along the work path 136 while the automatic cruise control by the vehicle speed controller 82 is being executed. When the traveling control unit 71 is instructed to end the automatic traveling, the vehicle speed controller 82 is controlled to decelerate the rice transplanter 1 and then stop the rice transplanter 1.

If the user instructs the end of the automatic driving while the automatic driving is being performed on the work route 136 while executing the auto cruise control, and if the auto cruise control is maintained, the user does not intend to reach a point. There is a possibility that rice transplanter 1 will progress. In this respect, according to the configuration of the present embodiment, the rice transplanter 1 can be stopped at a position close to the position at the time when the user instructs the end of the automatic running.

Further, in the automatic traveling system of the rice transplanter 1 of the present embodiment, the automatic traveling control unit 71 is a vehicle speed controller regardless of the operation amount of the speed change pedal 27 when the rice transplanter 1 automatically travels along the turning path 137. The 82 is controlled to limit the vehicle speed of the rice transplanter 1 to a predetermined upper limit vehicle speed or less.

As a result, in automatic traveling, the upper limit of the vehicle speed of the rice transplanter 1 is set on the turning path 137, so that the riding comfort can be improved.

Further, in the automatic traveling system of the rice transplanter 1 of the present embodiment, the automatic traveling control unit 71 waits until a predetermined condition is satisfied when the route for automatically traveling the rice transplanter 1 shifts from the turning path 137 to the working path 136. , Prevents the acceleration of the rice transplanter 1 by the vehicle speed controller 82. This predetermined condition is to operate the speed change pedal 27 on the deceleration side.

When the rice transplanter 1 that automatically travels shifts from the turning path 137 to the working path 136, if the upper limit of the vehicle speed applied on the turning path 137 is released, the rice transplanter 1 accelerates against the intention of the user. there is a possibility. In this regard, according to the configuration of the present embodiment, in order for the rice transplanter 1 that has moved to the work path 136 to accelerate, the speed change pedal 27 is once operated to the deceleration side and then to the speed increase side (a little release of the foot). It is necessary to perform an explicit operation such as stepping on. Therefore, it is possible to increase the user's sense of security regarding acceleration.

Although the preferred embodiment of the present invention has been described above, the above configuration can be changed as follows, for example.

In the present embodiment, the connection state / disconnection state of the left side clutch 55L or the right side clutch 55R is switched for the turning of the rice transplanter 1, and such switching is linked to the operation of the steering handle 26. It may be performed, or it may be performed based on the detection result of the steering angle sensor provided in the rice transplanter 1.

The wireless communication terminal 3 may be removed from the rice transplanter 1, and the operator may operate the wireless communication terminal 3 without getting on the rice transplanter 1 to cause the unmanned rice transplanter 1 to perform automatic driving.

The rice transplanter 1 may have a function corresponding to the wireless communication terminal 3. In this case, the rice transplanter 1 can realize an automatic traveling system for a work vehicle without the wireless communication terminal 3.

In view of the above teachings, it is clear that the present invention can take many modified and modified forms. Therefore, it should be understood that the invention may be practiced in ways other than those described herein, within the scope of the appended claims.

1 Rice transplanter (working vehicle)
14 Planting part (working part)
27 Speed change pedal (vehicle speed control unit)
82 Vehicle speed controller (vehicle speed controller)
71 Automatic driving control unit 123 Automatic driving operation unit 135 Driving route 136 Work route 137 Turning route E1 End point

Claims (7)

Using the positioning system, the work vehicle is automatically driven along a travel path having a plurality of work paths in which work is performed by the work unit and a turning path connecting adjacent work paths among the plurality of work paths. It is an automatic driving system for work vehicles equipped with an automatic driving control unit that can be operated.
The work vehicle includes a vehicle speed control unit that controls the vehicle speed of the work vehicle.
The automatic traveling control unit permits vehicle speed maintenance control for maintaining a predetermined vehicle speed by the vehicle speed control unit when the working vehicle is automatically driven along the work path, while the automatic traveling control unit permits the vehicle speed maintenance control along the turning path. An automatic traveling system for a working vehicle, which prohibits the vehicle speed maintenance control by the vehicle speed control unit when the working vehicle is automatically driven. The automatic traveling system for a work vehicle according to claim 1.
Even when the work vehicle is automatically driven along the work path, the automatic travel control unit may use the section from a predetermined point to the end point, which is a predetermined distance before the end point of the work path. An automatic traveling system for a work vehicle, characterized in that the vehicle speed maintenance control by the vehicle speed control unit is prohibited. The automatic traveling system for a work vehicle according to claim 2.
When the work vehicle is automatically driven along the work path in a state where the vehicle speed maintenance control is being executed by the vehicle speed control unit, the automatic travel control unit determines the position of the work vehicle. An automatic traveling system for a work vehicle, characterized in that when the vehicle reaches a point, the vehicle speed control unit is controlled to decelerate the work vehicle and then stop the work vehicle. The automatic traveling system for a work vehicle according to any one of claims 1 to 3.
The automatic traveling control unit can cause the working vehicle to start automatic traveling along the work route when the automatic traveling start condition is satisfied.
The automatic traveling system of a work vehicle, characterized in that the automatic traveling start condition includes the fact that the vehicle speed maintenance control is not executed by the vehicle speed control unit. The automatic traveling system for a work vehicle according to any one of claims 1 to 4.
It is provided with an automatic driving operation unit that can issue a start command and an end command for automatic driving of the work vehicle to the automatic driving control unit.
The automatic driving control unit operates the automatic driving operation unit when the work vehicle is automatically driven along the work path while the vehicle speed maintenance control is being executed by the vehicle speed control unit. When the automatic running end command is given to the automatic running control unit, the automatic running of the work vehicle is characterized in that the vehicle speed control unit is controlled to decelerate the work vehicle and then stop the work vehicle. system. The automatic traveling system for a work vehicle according to any one of claims 1 to 5.
When the work vehicle is automatically driven along the turning path, the automatic driving control unit controls the vehicle speed control unit to control the vehicle speed of the work vehicle regardless of the operation amount of the vehicle speed operation unit. An automatic driving system for work vehicles, which is characterized by limiting the vehicle speed to a predetermined upper limit or less. The automatic traveling system for a work vehicle according to claim 6.
When the automatically traveling work vehicle shifts from the turning path to the work path, the automatic driving control unit prevents the vehicle speed control unit from accelerating the work vehicle until a predetermined condition is satisfied.
The predetermined condition is an automatic traveling system of a work vehicle, characterized in that the vehicle speed operation unit is operated to the deceleration side.

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