JP2023020449A - seedling transplanter - Google Patents

Abstract

To provide a seedling transplanter capable of electrically driving a travel wheel.SOLUTION: A seedling transplanter includes: a travel vehicle body having travel wheels including a steering wheel and capable of traveling in a field; and a planting device that plants a seedling in the field. The travel vehicle body includes a motor that drives the travel wheels and a battery that drives the motor. A power generator for charging the battery is provided. The power generator is not mounted on the travel vehicle body. A connector for charging the battery is provided in a front side of the travel vehicle body. The power generator can charge the travel vehicle body being stop in a levee side.SELECTED DRAWING: Figure 32

Description

The present invention relates to a seedling transplanter.

2. Description of the Related Art Conventionally, there is known a working vehicle having an automatic mode in which a traveling vehicle body autonomously travels in a field while performing work by driving traveling wheels with an engine (see, for example, Patent Document 1).

JP 2020-141615 A

There has been a demand for a seedling transplanter that considers the environmental performance of a motorized plant.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a seedling transplanter capable of electrically driving running wheels without impairing workability.

In order to solve the above-described problems and achieve the object, the seedling transplanter according to the present invention has a traveling wheel including a steering wheel, a traveling body capable of traveling in a field, and a planting machine for planting seedlings in the field. and a motor for driving the running wheels and a battery for driving the motor are provided on the traveling vehicle body.

According to the seedling transplanter according to the present invention, the running wheels can be electrically driven and the environmental performance can be improved.

FIG. 1 is a schematic left side view showing the work vehicle according to the embodiment. FIG. 2 is a schematic plan view showing the work vehicle according to the embodiment. FIG. 3 is a block diagram showing an example of a control system centered on a control device. FIG. 4 is an explanatory diagram of autonomous running in a field. FIG. 5 is a diagram illustrating the mode configuration performed by the controller. FIG. 6 is a diagram showing an example of work area information acquisition in the teaching mode. FIG. 7 is a front view showing the remote controller. FIG. 8 is a diagram showing a display example of the top screen (No. 1) on the remote control side display unit. FIG. 9 is a diagram showing a display example of the top screen (No. 2) on the remote controller side display unit. FIG. 10 is a diagram showing a display example of the top screen (No. 3) on the remote control side display unit. FIG. 11 is a diagram showing a display example of the top screen (No. 4) on the remote control side display unit. FIG. 12 is a diagram showing a display example of a mode screen on the remote control side display unit. FIG. 13 is a diagram showing a display example of a menu screen (Part 1) on the remote control side display unit. FIG. 14 is a diagram showing a display example of a menu screen (part 2) on the remote control side display unit. FIG. 15 is a diagram showing a display example of a menu screen (part 3) on the remote control side display unit. FIG. 16 is a diagram showing an example of a screen displayed on the remote control side display unit during teaching. FIG. 17 is a diagram showing a screen display example (Part 1) on the body-side display unit. FIG. 18 is a diagram showing a display example (part 2) of a screen on the body-side display unit. FIG. 19 is a diagram showing a display example (part 3) of a screen on the body-side display unit. FIG. 20 is a diagram showing an example (part 4) of screen display on the body-side display unit. FIG. 21 is a diagram showing a display example (No. 5) of a screen on the body-side display unit. FIG. 22 is a diagram showing a screen display example (No. 6) on the body-side display unit. FIG. 23 is a diagram showing a display example (No. 7) of a screen on the body-side display unit. FIG. 24 is a diagram showing a display example (No. 8) of a screen on the body-side display unit. FIG. 25 is a diagram showing a display example (No. 9) of a screen on the body-side display unit. FIG. 26 is a diagram showing a screen display example (No. 10) on the body-side display unit. FIG. 27 is a diagram showing a display example (No. 11) of a screen on the body-side display unit. FIG. 28 is a diagram showing a display example (No. 12) of a screen on the body-side display unit. FIG. 29 is a diagram showing another example of work area information acquisition in the teaching mode. FIG. 30 is a diagram showing a standing steering assist mechanism (No. 1). FIG. 31 is a diagram showing a standing steering assist mechanism (No. 2). FIG. 32 is a diagram showing an electric drive and generator.

Hereinafter, embodiments of a work vehicle disclosed in the present application will be described in detail with reference to the accompanying drawings. In addition, this invention is not limited by embodiment shown below.

<Overview of work vehicle (seedling transplanter)>
First, an outline of a work vehicle (seedling transplanter) 1 according to an embodiment will be described with reference to FIGS. 1 and 2. FIG. FIG. 1 is a schematic left side view showing a working vehicle (seedling transplanter) 1 according to the embodiment. FIG. 2 is a schematic plan view showing the work vehicle (seedling transplanter) 1 according to the embodiment.

In the following description, the front-rear direction is the traveling direction of the work vehicle 1 when the work vehicle 1 travels straight. The traveling direction of the work vehicle 1 is the direction from the later-described driver's seat 41a to the steering wheel 35 when traveling straight (see FIGS. 1 and 2).

The left-right direction is a direction that is horizontally perpendicular to the front-rear direction, and defines left and right toward the "front" side. That is, when an operator (also called an operator) is seated in the operator's seat 41a and faces forward, the left hand side is "left" and the right hand side is "right".

Also, the vertical direction is the vertical direction. The front-back direction, the left-right direction, and the up-down direction are orthogonal to each other. Each direction is defined for convenience of explanation, and the present invention is not limited by these directions. In the following description, the work vehicle (seedling transplanter) 1 or the traveling vehicle body 2 to be described later may be referred to as the "body".

As shown in FIGS. 1 and 2 , work vehicle 1 includes traveling vehicle body 2 and work implement 4 . In this embodiment, the work vehicle is described as a ride-on type seedling transplanter 1 that includes a seedling planting unit 4 as a work machine and plants seedlings on the soil surface of a field. The seedling transplanter 1 is equipped with an elevable seedling planting part 4 for planting seedlings in a field on the rear side of a traveling vehicle body 2 via an elevating link mechanism 3. - 特許庁

A fertilizing device 5 is arranged on the rear upper side of the traveling vehicle body 2 . If the work vehicle 1 is not the seedling transplanter 1, it may be equipped with a seeding device for supplying seeds as a work machine.

The traveling vehicle body 2 includes steering wheels and drive wheels as traveling wheels. The traveling vehicle body 2 includes a pair of left and right front wheels 10 and a pair of left and right rear wheels 11 . In the traveling vehicle body 2, a pair of left and right front wheels 10 are used as steered wheels. In the vehicle body 2, the driving wheels are the pair of left and right rear wheels 11, or the pair of left and right front wheels 10 and the pair of left and right rear wheels 11.

A transmission case 13 for transmitting driving force to the seedling planting portion 4 and the like and a driving force supplied from the engine 30, that is, the driving force generated by the engine 30, are provided on the front side of the main frame 15 constituting the vehicle body frame of the traveling vehicle body 2. A hydraulic continuously variable transmission 14 that outputs rotation to the mission case 13 is provided.

The continuously variable transmission 14 is a hydrostatic continuously variable transmission called HST (Hydro Static Transmission). A case where the continuously variable transmission is the HST 14 will be described below.

Inside the transmission case 13, an auxiliary transmission mechanism 16 is provided for switching the traveling mode of the traveling vehicle body 2, such as when traveling on the road in high speed mode or when planting seedlings in low speed mode. Front wheel final cases 10a are provided on the left and right sides of the transmission case 13. Left and right front axles 10b protrude outward from front wheel support portions capable of changing the steering direction of the left and right front wheel final cases 10a, respectively. 10 is attached.

On the rear side of the main frame 15, a rear wheel gear case 11a is attached to both left and right sides of a rear frame 22 (see FIG. 2) provided in the lateral direction. The rear wheels 11 are attached to the rear axles 11b, respectively.

Left and right link support frames 23 for supporting the lifting link mechanism 3 project upward from the upper portion of the rear frame 22 . A pair of left and right lower link arms 24 are provided on the lower side of the left and right link support frames 23 and between the left and right. An elevating cylinder 25 that operates hydraulically is provided between the left and right lower link arms 24 .

An upper link arm 26 is provided above the lifting cylinder 25 to constitute the lifting link mechanism 3, which is a parallel link mechanism. The left and right lower link arms 24, the elevating cylinders 25, and the other ends of the upper link arms 26, each of which has one end connected to the traveling vehicle body 2, are attached to the front portion of the seedling planting section 4. .

An engine 30 is mounted on the main frame 15 . Rotational power of engine 30 is transmitted to mission case 13 via belt transmission device 21 and HST 14 . The rotational power transmitted to the mission case 13 is shifted by the sub-transmission mechanism 16 in the mission case 13, and then divided into running power and external power.

Also, the rotational power of the engine 30 is transmitted to a hydraulic pump (not shown). The hydraulic pressure generated by the hydraulic pump is supplied to the HST 14, the power steering mechanism 89 (see FIG. 3) of the steering wheel 35, the lifting cylinder 25, and the like.

The external extraction power extracted from the rotational power transmitted to the transmission case 13 is transmitted to the planting clutch case 27 provided at the rear part of the traveling vehicle body 2, and the seedlings are planted from the planting clutch case 27 by the planting transmission shaft 67. It is transmitted to the part 4.

On the other hand, left and right drive shafts 42 are provided in the rear portion of the transmission case 13 . Rotational power from the engine 30 is transmitted to the left and right rear wheel gear cases 11 a via the transmission case 13 and the drive shaft 42 .

A side clutch 44 (see FIG. 3) for turning on and off power transmission to the left and right drive shafts 42 is arranged on the upper side of the left and right drive shafts 42 in the power transmission direction. As shown in FIG. 1, a side clutch pedal 43a for turning on and off the left and right side clutches 44 is provided at the front lower portion of the operator's seat 41a and on one of the left and right sides.

Of the right and left side clutch pedals 43a, the side clutch pedal 43a on the inner side of the turn is depressed to disengage the side clutch 44, and then the handle 35 is operated to make the turn. can be blocked.

A bonnet 39 is provided on the upper front side of the traveling vehicle body 2. A control panel 38 for operating each part is arranged on the upper part. The control panel 38 is provided with a display section 86 (see FIG. 3) for displaying predetermined information, and the like.

Further, the bonnet 39 is provided with a steering wheel 35 for steering the traveling vehicle body 2, a shift operation lever 36 for operating the HST 14 and the seedling planting section 4, an auxiliary shift operation lever 37 for operating the auxiliary transmission mechanism 16, and the like. The operator's seat 41 a , the steering wheel 35 , the shift operating lever 36 , the sub-shift operating lever 37 , etc. constitute a control section 41 in the seedling transplanter 1 in which the operator (operator) gets on.

A front cover 40 that can be opened and closed is provided on the front side of the bonnet 39 . Inside the front cover 40, there are provided a fuel tank, a battery, and an interlocking mechanism for rotating the left and right front wheels 10 and the lower portions of the left and right front wheel final cases 10a in response to the steering operation of the steering wheel 35. The front wheels 10 are steering wheels that steer the body according to the steering amount of the steering wheel 35, as described above.

An engine cover 30a is provided behind the bonnet 39 and above the engine 30 to cover the upper and side portions of the engine 30. Above the engine cover 30a is an operator's seat 41a. be provided.

A fertilizing device 5 is provided on the rear side of the cockpit 41 a and on the rear end side of the main frame 15 . The driving force of the fertilizing device 5 is transmitted by a fertilizing transmission mechanism provided so as to face the fertilizing device 5 from one of the left and right sides of the left and right rear wheel gear cases 11a.

Approximately horizontal floor steps 33 are formed on both left and right sides of the lower portion of the engine cover 30a and the bonnet 39 . As shown in FIG. 2, the floor step 33 is partially lattice-shaped, and for example, even if mud adheres to the shoes of the operator (worker) walking on the floor step 33, the mud that has fallen may reach the field. Fall.

A rear step 330 is connected to the rear of the floor step 33 as shown in FIG. The surface of the rear step 330 is preferably provided with anti-slip processing, for example, with a plurality of projection patterns formed thereon so that feet do not slip easily during work.

In addition, on the front side of the traveling vehicle body 2 and on both the left and right sides, there are provided preliminary seedling frames 50 on which a plurality of preliminary seedling mounting bases 52 are arranged on seedling frame supports 51 at intervals in the vertical direction. Work materials such as seedlings (seedling mats) and fertilizer bags to be replenished on the attached portion 4 can be placed.

A seedling tank 53 for loading seedlings (seedling mat) to be planted in the field is mounted on the rear end of the lifting link mechanism 3 together with a sliding mechanism for sliding in the left-right direction. In the seedling tank 53, vertically long seedling partition fences 54 are arranged at predetermined intervals in the horizontal direction. Below the seedling tank 53, a seedling planting device 55 for scraping seedlings from the loaded seedling mats and planting them in the field is arranged.

The seedling planting device 55 has the same number of planting rows as the number of planting rows separated by the seedling partition fence 54, that is, plants eight rows at the same time. A planting rotary 57 is mounted on each of the right and left sides of the planting transmission case 56 to pick up seedlings by a planting rod 58 and plant them in the field while rotating.

In the fertilizing device 5, a fertilizing hopper 70 in which fertilizer is stored is divided into the same number of working rows as the seedling planting section 4 (eight rows in the example shown in FIG. 2). In addition, since the fertilizing hoppers 70 for eight rows are long in the left-right direction, the convenience of putting in and removing fertilizer is reduced. good too.

Below the fertilizing hopper 70, a delivery device 71 for supplying a set amount of fertilizer for each row is provided. Below the delivery device 71, a ventilation duct 72 through which the conveying air for moving the fertilizer passes is provided in the left-right direction. A fertilizing hose 73 for guiding fertilizer to the vicinity of the seedling planting position of the seedling planting section 4 is provided below the delivery device 71 . A blower 74 is provided at one end of the ventilation duct 72 and is operated by a blower electric motor 76 to generate a carrier air.

As shown in FIGS. 1 and 2, below the seedling planting unit 4, there are a center float 62C that slides in contact with the field surface, and two left and right side floats 62L and 62R that rotate about their axes. It is provided movably. Note that the center float 62C and the left and right side floats 62L and 62R may be collectively referred to as the floats 62 in some cases.

In addition, the seedling planting unit 4 has a leveling rotor 63 that is arranged on the front side of the float 62 and levels the unevenness of the field. The seedling planting unit 4 plants seedlings on the soil surface leveled by the leveling rotor 63 . Driving force is transmitted to the ground leveling rotor 63 from the rear wheel gear case 11a through a rotor transmission shaft 63a. The seedling planting unit 4 is driven and controlled by a control device 100 (see FIG. 3), which will be described later.

Further, as shown in FIG. 1, on both the left and right sides of the seedling planting part 4, one of the left and right sides is in contact with the field, and a groove is formed as a guideline for running in the next work row (next process). A delineation marker 65 is provided respectively. The left and right line markers 65 move upward when one of the left and right sides touches the ground, and when the seedling planting unit 4 is raised during rotation, both left and right sides move upward. One of the left and right sides is spaced upward and the other side is grounded.

Further, as shown in FIGS. 1 and 2 , a center mascot 66 that is elongated in the vertical direction is provided at the left-right central portion of the traveling vehicle body 2 and in front of the bonnet 39 . By aligning the center mascot 66 with the groove formed in the field by the left and right line drawing markers 65, it is possible to travel in line with the working position of the immediately preceding work line, improving work accuracy and preventing the occurrence of non-work. be able to.

Note that depending on the soil quality of the field, the guide line formed by the left and right line markers 65 may quickly become buried, and the guideline for straight running may disappear. In such a case, it is preferable to use the left and right side markers 19 provided on the front side of the left and right delineation markers 65 . That is, by moving the left and right side markers 19 outward and positioning the side markers 19 above the planted seedlings, the planting operation can be performed in accordance with the planting of the seedlings of the previous working row.

Moreover, as shown in FIG. 1 , the seedling transplanter 1 includes a position acquisition device 150 . The position acquisition device 150 acquires the current position and orientation of the seedling transplanter 1 . The position acquisition device 150 includes, for example, an orientation sensor and positioning means such as GPS (Global Positioning System) and GNSS (Global Navigation Satellite System). Note that the position acquisition device 150 may be composed of a plurality of devices. The position acquisition device 150 may also include a camera or an ultrasonic sensor, acquire a turning position in the field, and detect the distance to the turning position.

The position acquisition device 150, for example, receives positioning information from the positioning means, creates current position information and direction information of the traveling vehicle body 2 based on the received positioning information, and acquires the current position and direction. The position acquisition device 150 is attached to, for example, the attachment stay 59 and arranged above the traveling vehicle body 2 .

Also, the straight-line control program and the turning control program, which are created based on the position information obtained by the position acquisition device 150, are stored in separate locations. The straight running control program is stored, for example, in a straight running control ECU (Electronic Control Unit) in the position acquisition device 150 , and the turning control program is stored, for example, in a turning control ECU housed in the bonnet 39 . Note that the straight running control ECU and the turning control ECU are included in a control device 100 (see FIG. 3), which will be described later. Note that the straight running control ECU and the turning control ECU may be the same ECU.

<Control system of work vehicle (seedling transplanter)>
Next, the control system of the work vehicle (seedling transplanter) 1 (see FIGS. 1 and 2) will be described with reference to FIG. FIG. 3 is a block diagram showing an example of a control system centering on the control device 100. As shown in FIG. The seedling transplanter 1, which is a work vehicle, is capable of controlling each part by electronic control, and includes a control device 100 for controlling each part.

The control device 100 includes, for example, a processing unit having a CPU (Central Processing Unit), a storage unit such as a ROM (Read Only Memory) and a RAM (Random Access Memory), and an input/output unit. They are connected to each other and can exchange signals with each other. A computer program for controlling the seedling transplanter 1 and the like are stored in the storage unit. The control device 100 performs each function by reading a computer program or the like stored in the storage unit.

The control device 100 includes, for example, actuators such as a throttle motor 80, a hydraulic control valve 81, a hydraulic control valve 82, a plant clutch actuation solenoid 83, a side clutch actuation solenoid 84, an HST motor 85, a draw marker lifting motor 88, a steering wheel A device 95, a differential lock switching motor 96, and the like are connected.

The throttle motor 80 increases or decreases the rotation speed of the output shaft of the engine 30 by operating a throttle that adjusts the intake air amount of the engine 30 . The hydraulic control valve 81 controls the expansion and contraction of the elevating cylinder 25 . A hydraulic control valve 82 controls a power steering mechanism 89 . The planted clutch actuating solenoid 83 operates the planted clutch 27a.

The side clutch actuation solenoid 84 actuates the side clutch 44 that switches the state of power transmission to the rear wheels 11 (see FIGS. 1 and 2). The side clutches 44 are provided for the left and right rear wheels 11 respectively, and two side clutch actuation solenoids 84 are provided corresponding to the respective side clutches 44 .

The HST motor 85 changes the tilt angle of the swash plate of the HST 14 by changing the rotation angle of the trunnion of the HST 14 . The steering device 95 steers and drives left and right front wheels 10 (see FIGS. 1 and 2), which are steering wheels. The steering device 95 has a steering motor 95a. The steering motor 95a is a motor that drives the steering wheel 35 that adjusts the amount of steering of the front wheels 10 (also referred to as steering angle or turning angle) when automatic turning control is performed. The steering motor 95 a rotates the steering wheel 35 . A drawing marker lifting motor 88 raises and lowers the drawing marker 65 .

The differential lock switching motor 96 is a motor that switches between operating and stopping a differential lock mechanism 97 (hereinafter referred to as differential lock mechanism) that rotates the left and right running wheels (for example, the left and right front wheels 10) at the same rotational speed. By engaging the differential lock mechanism 97, four-wheel drive can be forcibly set, and the left and right running wheels rotate at the same rotational speed.

A rotational speed sensor 90, a steering amount sensor 91, an inclination sensor 92, and the like are connected to the control device 100. FIG. Two rotation speed sensors 90 are provided corresponding to the left and right rear wheels 11, and detect the rotation speeds of the left and right rear wheels 11, respectively. Note that the rotation speed sensor 90 may detect the rotation speed of the left and right front wheels 10 .

The steering amount sensor 91 detects the amount of steering of the steering wheel 35, that is, the amount of steering of the front wheels 10 (steering angle, turning angle). The steering amount sensor 91 is provided, for example, on a shaft connected to the pitman arm. Note that the steering amount is detected in each of the left and right directions using the value when the steering wheel 35 is in a preset straight-ahead position as a reference value.

Also, a plurality of steering amount sensors 91 may be provided. Also, the steering amount sensor 91 may be provided at a plurality of locations. Detection accuracy of the steering amount of the front wheels 10 can be improved by detecting the steering amount of the front wheels 10 using a plurality of steering amount sensors 91 . The tilt sensor 92 detects the tilt angle, which is the tilt of the traveling vehicle body 2 .

The control device 100 also receives operation signals from a shift operation lever 36, an auxiliary shift operation lever 37, a mode changeover switch 46, a seedling planting section up/down switch 47, an automatic turn changeover switch 48, a drawing marker automatic up/down switch 49, and the like. A signal is input.

The mode changeover switch 46 is a switch that changes over whether to execute autonomous driving. The mode changeover switch 46 is a switch for switching between an automatic mode, a manual mode, and a remote control mode, which will be described later.

The seedling planting part elevating switch 47 is a switch for switching whether or not the seedling planting part 4 is moved up and down. The seedling planting section lift switch 47 is changed to the "raise" and "lower" positions.

When the seedling planting section lift switch 47 is at the "up" position, the seedling planting section 4 rises to a predetermined non-working position, and the seedling planting device 55 is stopped in a non-working state (seedling planting section 4). is turned off). When the seedling planting section lift switch 47 is at the "down" position, the seedling planting section 4 is lowered to a predetermined working position, and the seedling planting device 55 (see FIGS. 1 and 2) is in a working state. (Entered state of the seedling planting unit 4). That is, the seedling planting section lift switch 47 is a switch for detecting the working state of the seedling planting section 4 .

The drawing marker automatic elevation switch 49 is a switch for switching whether to automatically raise or lower the drawing marker 65 in conjunction with the steering amount of the steering wheel 35 (that is, the steering amount of the front wheels 10). When the drawing marker automatic elevation switch 49 is "ON", control is executed to automatically raise and lower the drawing marker 65 in conjunction with the steering amount. On the other hand, when the drawing marker automatic elevation switch 49 is "OFF", the control for automatically raising and lowering the drawing marker 65 in conjunction with the steering amount is not executed.

The automatic turning changeover switch 48 is a switch for switching whether or not automatic turning can be executed in the manual mode, for example. Note that when the automatic turning changeover switch 48 is turned "ON", automatic turning can be executed. When the automatic turning switch 48 is "OFF", automatic turning cannot be executed.

A display unit 86 and a setting unit 87 are connected to the control device 100 . The display unit 86 is, for example, a liquid crystal monitor, and is arranged on the control panel 38 of the control unit 41 (see FIGS. 1 and 2 for both). The setting unit 87 is, for example, a push button, and is arranged near the display unit 86 on the operation panel 38 of the operation unit 41, for example. When the display unit 86 is a touch panel monitor, the setting unit 87 is arranged in the screen of the display unit 86. FIG.

The display unit 86 includes a body-side display unit 86a arranged in the operation unit 41 and a remote control-side display unit 86b arranged in a remote control device 160, which will be described later. Therefore, the operator can use the body side display section 86a when boarding and operating the body, and can use the remote control side display section 86b when remotely controlling the body with the remote control device 160. FIG. In this way, the display unit 86 has the machine-body-side display unit 86a and the remote control-side display unit 86b, so that the operator can receive information during execution of any of the automatic mode, the remote control mode, and the manual mode. can be easily grasped.

In addition, the display unit 86 displays a setting screen for preset reference values of each unit in the traveling vehicle body 2 , the seedling planting unit 4 and the fertilizing device 5 . The display unit 86 displays, for example, reference values for the seedling amount and planting depth in the seedling planting unit 4, the hydraulic pressure sensitivity in the seedling planting unit 4, the turning on/off of the seedling planting unit 4, and the height of the leveling rotor 63. Display the setting screen. The setting unit 87 receives a reference value setting operation by the operator. In other words, the operator can perform input operation and change operation of the reference value from the setting unit 87 .

A remote control device 160 is connected to the control device 100 so as to be able to communicate with each other, and various information is input from the remote control device 160 . Control device 100 receives various types of information from remote control device 160 via receiver 180 (see FIG. 1), for example. The receiver 180 is mounted, for example, on the mounting stay 59 (see FIG. 1) and arranged above the front side of the traveling vehicle body 2 . A plurality of receivers 180 may be provided.

Remote control device 160 is operated by an operator when executing a remote control mode, which will be described later. The remote control device 160 can remotely control the seedling transplanter 1 . Remote control device 160 transmits a control signal according to an operator's operation to control device 100 . Remote control device 160 may be communicably connected to control device 100 by short-range wireless communication such as Wi-fi (registered trademark) or BLE (Bluetooth (registered trademark) Low Energy). In addition to communication (or instead of short-range wireless communication), they may be communicatively connected via a communication network or the like.

Further, remote control device 160 includes, for example, a direction sensor and positioning means such as GPS and GNSS. Remote control device 160 transmits the position information of remote control device 160 to control device 100 . Based on the position information of remote control device 160 and the position information of traveling vehicle body 2 , control device 100 calculates the distance between remote control device 160 and traveling vehicle body 2 and the azimuth of remote control device 160 with respect to traveling vehicle body 2 . The remote control device 160 includes a remote control side display section 86b and a remote control side operation section 87b that constitute the display section 86 . Details of remote control device 160 will be described later with reference to FIG.

In this way, the control device 100 receives the current position information of the traveling vehicle body 2 from the position acquisition device 150, and the like, so that the control device 100 controls the steering device 95 and also controls the traveling vehicle body 2 (FIGS. 1 and 2). 2) can be made to run autonomously. The control device 100 executes an automatic mode, which will be described later, in which work is performed while the traveling vehicle body 2 autonomously travels.

<Auto mode>
Here, autonomous traveling (automatic mode) in a field by the seedling transplanter 1 will be described with reference to FIG. 4 . FIG. 4 is an explanatory diagram of autonomous running in a field. The control device 100 (see FIG. 3) has an automatic mode in which the steering device 95 (see FIG. 3) is automatically controlled while feeding back the steering amount of the front wheels 10 (see FIGS. 1 and 2). The control device 100 operates the steering wheel 35 (see FIG. 3) by controlling the steering device 95 in the automatic mode. Automatic mode includes automatic straight control and automatic turning control.

In the automatic mode, the control device 100 causes the traveling vehicle body 2 to travel autonomously. The control device 100 controls the traveling direction of the traveling vehicle body 2 by controlling the steering wheel 35 during autonomous traveling. Further, the control device 100 controls the speed (vehicle speed) of the traveling vehicle body 2 by controlling the rotation speed of the engine 30 during autonomous travel. Note that the control device 100 may control the speed of the traveling vehicle body 2 by performing a brake operation during autonomous travel.

As shown in FIG. 4, in the automatic mode, the seedling transplanter 1 automatically performs seedling planting work while repeating straight and turning along the planned travel route L in the field. As described above, the control device 100 acquires the current position information and the turning position information of the seedling transplanter 1 by the position acquisition device 150 (see FIG. 1) arranged above the traveling vehicle body 2 .

The seedling transplanter 1 plants seedlings while reciprocating within a predetermined work area in a field. In this case, for straight traveling, the control device 100 executes automatic straight traveling control, whereby autonomous traveling is performed along the straight traveling route L1 of the set planned traveling routes L. FIG. As for the turning travel, automatic turning along the turning travel route L2 of the planned travel route L is performed by the control device 100 executing automatic turning control.

The straight travel route L1 is parallel to the reference line L0 that serves as a travel reference. The reference line L0 is set in the field according to the seedling planting direction. For example, control device 100 acquires the start position and end position of straight running as reference start point P1 and reference end point P2, respectively, and stores a line segment connecting reference start point P1 and reference end point P2 as reference line L0.

The control device 100 controls the steering device 95 (steering motor 95a) so that the steering amount of the steering wheel 35 becomes a predetermined steering amount while the seedling transplanter 1 is turning. The predetermined steering amount is a preset value. The predetermined steering amount is set according to the type of the seedling transplanter 1 and the like. Further, the predetermined steering amount is appropriately set so that the transition from automatic turning to automatic straight running is smoothly performed.

The control device 100 determines that the seedling transplanter 1 reaches any desired position on the set turning travel path L2 based on the position information acquired by the position acquisition device 150 while the seedling transplanter 1 is turning. The steering device 95 (steering motor 95a) may be controlled to do so.

The control device 100 controls the steering device 95 (steering motor 95a) so that the seedling transplanter 1 reaches the planting start position by automatic straight movement in the next step after turning by automatic turning.

The control device 100 controls the steering device 95 (steering motor 95 a ) based on the steering amount of the steering wheel 35 detected by the steering amount sensor 91 when autonomous driving is executed. Specifically, the control device 100 compares the steering amount of the steering wheel 35 detected by the steering amount sensor 91 with a reference value, and controls the steering device 95 (steering motor 95a) based on the comparison result.

<Various modes>
Each mode, including the automatic mode, executed by the control device 100 will now be described. FIG. 5 is a diagram showing a mode configuration executed by control device 100. As shown in FIG. As shown in FIG. 5, control device 100 (see FIG. 3) has a first mode, a second mode, a teaching mode, and a four-wheel drive mode.

The first mode is a mode in which the traveling vehicle body 2 (see FIGS. 1 and 2) can autonomously travel. The control device 100 has an automatic mode and a remote control mode in the first mode. That is, the first mode includes an automatic mode and a remote control mode.

The automatic mode is a mode for automatically controlling the steering device 95 (see FIG. 3), and includes the above-described automatic straight driving control and automatic turning control. In the automatic mode, the control device 100 causes the traveling vehicle body 2 to travel along the planned travel route L (see FIG. 4) while repeating straight ahead and turning.

The remote control mode is a mode in which the steering device 95 is controlled based on remote control by the operator. In the remote control mode, the operator operates the remote control device 160 (see FIG. 3) to operate the machine body.

Thus, by having the automatic mode and the remote control mode in the first mode, for example, the traveling vehicle body 2 can be moved in the remote control mode from outside the field to a work start point in the field. Workability can be improved, for example, by eliminating the troublesomeness of a worker operating the body to move the traveling vehicle body 2 and then walking in the field to get out of the field.

During execution of the remote control mode, the control device 100 stops the autonomous travel of the traveling vehicle body 2 , that is, stops the automatic mode, and accepts only machine body operations based on operation signals from the remote control device 160 .

According to such a configuration, remote control by the remote control device 160 becomes possible in the remote control mode. Further, in this case, since the autonomous traveling is stopped, it is possible to prevent unintended traveling of the traveling vehicle body 2 during remote operation by the remote control device 160, thereby improving safety. In addition, even during the execution of the automatic mode, the traveling vehicle body 2 switches to the remote control mode when it approaches the ridge, so that the autonomous traveling stops at the ridge. becomes possible.

Further, even during execution of the automatic mode, the control device 100 shifts to the remote control mode so that the operator can operate the turning of the machine body when the traveling vehicle body 2 reaches the point where the turning is started. In this case, the control device 100 shifts to the remote control mode based on the mode switching operation signal from the remote control device 160 .

According to such a configuration, by switching to the remote operation mode by operating the remote control device 160, erroneous operation can be suppressed, thereby improving safety.

Further, the control device 100 operates each part including the seedling planting part 4 (see FIGS. 1 and 2) based on the operation signal from the remote control device 160 during execution of the automatic mode. Thereby, the operator can adjust each part including the seedling planting part 4 from the remote control device 160 during execution of the automatic mode.

Thus, even in the automatic mode, it is possible to receive a remote operation from the remote control device 160 and remotely operate each part including the seedling planting part 4 during execution of the automatic mode, so that workability can be improved. .

In this case, control device 100 does not accept an operation signal relating to steering device 95 among the operation signals from remote control device 160 during execution of the automatic mode. In this way, during execution of the automatic mode, an operation signal relating to the steering device 95 from the remote control device 160 is not accepted, that is, an operation of the steering device 95 from the remote control device 160 is not accepted, thereby preventing erroneous driving operations. be able to.

Further, the control device 100 performs various adjustments according to operation signals from the remote control device 160 during execution of the automatic mode. Specifically, the control device 100 controls the start, stop, and temporary stop of the traveling vehicle body 2, the speed of the traveling vehicle body 2, the seedling amount and planting depth in the seedling planting section 4, and the hydraulic pressure sensitivity in the seedling planting section 4. , turn on/off the seedling planting unit 4, and adjust the height of the leveling rotor 63. Further, the control device 100 switches to a four-wheel drive mode (forced four-wheel drive), which will be described later, according to an operation signal from the remote control device 160 during execution of the automatic mode.

According to such a configuration, various adjustments can be made remotely while the automatic mode is being executed, so workability can be improved.

Further, during execution of the automatic mode, when the traveling vehicle body 2 reaches the point where the turning ends, the control device 100 controls the seedling amount and the planting depth in the seedling planting section 4, the oil pressure sensitivity in the seedling planting section 4, and the , turning the seedling planting unit 4 on and off, and the height of the leveling rotor 63 are returned to the preset reference values described above.

According to such a configuration, when straight movement and turning of the aircraft are set as one process, by returning the value changed in the previous process to the reference value when moving to the next process, Various adjustments can be easily made, and workability can be improved.

In addition, the control unit 41 sets reference values for the seedling amount and planting depth in the seedling planting unit 4, the oil pressure sensitivity in the seedling planting unit 4, the turning on/off of the seedling planting unit 4, and the height of the leveling rotor 63. , the setting operation can be easily performed.

In response to an operation signal from the remote control device 160 during execution of the remote control mode, the control device 100 steers the steered wheels (front wheels 10) by the steering device 95, advances, reverses and stops the traveling vehicle body 2, and controls the seedling planting section. 4, switching to the four-wheel drive mode (forced four-wheel drive), and switching the state of the spare seedling frame (seedling rail) 50 (switching between the rail state and the loaded state). As a result, various adjustments can be made remotely while the remote operation mode is being executed, so workability can be improved. The state of the spare seedling frames (seedling rails) 50 can be switched only while the traveling vehicle is stopped.

The second mode is a mode in which the operator of the traveling vehicle body 2 can manually travel. The controller 100 has a manual mode in the second mode. The manual mode is a mode in which the operator performs body operations including steering operations and gear shift operations.

The teaching mode is a mode in which field information (information such as the shape of the field) is acquired by running the traveling vehicle body 2 in the field where work is to be performed in order to execute the automatic mode. Note that the control device 100 executes the manual mode in the teaching mode. Therefore, in the teaching mode, the farm field information is acquired by causing the traveling vehicle body 2 to travel in the farm field where the work is to be performed by manual operation by the operator.

FIG. 6 is a diagram showing an example of work area information acquisition in the teaching mode. As shown in FIG. 6, as work area information, when the farm field F in which work is performed is not rectangular, but has an irregular shape such as an L-shape, the control device 100 sets the straight traveling route L0 ₁ of the traveling vehicle body 2. _˜L03 , it can be determined that the lengths of the three sides E1 to E3 of the field F are different, and it is determined from the determination result that the field is not rectangular.

Then, when the control device 100 determines that the farm field F in which the work is performed is not rectangular in the teaching mode, in the automatic mode, the vehicle travels in the area A1 where the traveling vehicle body 2 can autonomously travel (the hatched area in FIG. 6). After that, switch to manual mode. In the example shown in FIG. 6, the control device 100 can determine the area A1 in which the traveling vehicle body 2 can autonomously travel from the straight traveling routes L0 ₁ to L0 ₅ , for example.

According to such a configuration, when the field F to be worked is an irregularly shaped field F such as an L-shape, the automatic mode is executed in the rectangular area A1 in which the traveling vehicle body 2 can autonomously travel. The manual mode is executed in an area A2 other than the area A1 in which autonomous driving is possible according to 2. As a result, even in an irregularly shaped field F, work can be efficiently performed by combining the automatic mode and the manual mode.

In the teaching mode, the control device 100 determines the shape of the field F by teaching the three sides as described above. is also possible.

Teaching by two sides is teaching used, for example, in a U-shaped field consisting of one vertically long rectangular portion and two horizontally long rectangular portions, when the vertically long rectangular portion is not planted and traveled.

Teaching by two sides does not perform full automatic turning on both ridges (sides). In the case of teaching using two sides, it is necessary to operate the remote control device 160 to move the traveling vehicle body 2 forward to the edge of a ridge and stop it, as in the case of teaching using three sides. Further, when it is desired to turn to the next process after the traveling vehicle body 2 has stopped, the function button 8707 and the start button 8709 (both of which are shown in FIG. 7) of the remote control device 160 are pressed to automatically turn to move to the next process. (resume autonomous driving). In addition, the vehicle automatically stops (stops) when it shifts to the remote control mode near the ridge on the side where teaching is not being performed. In addition, it is possible to turn to the next process even from the position where the vehicle is stopped. That is, the operation of the start button 8709 is accepted.

Teaching by four sides, for example, runs in a concave farm field with empty planting without planting on the last side. The fourth and final side corresponds to the line for transitioning from automatic mode to remote control mode. If four sides (sides including the dent on the upper side) are deformed in a concave field, the traveling vehicle body is stopped (stopped) in response to the deformed shape around the center of the field, and the mode is shifted to the remote control mode. It is possible to turn by operating from the remote control device.

The four-wheel drive mode (also called forced four-wheel drive mode) is a mode in which the pair of left and right front wheels 10 and the pair of left and right rear wheels 11 are driven together. In the four-wheel drive mode, the differential lock mechanism 97 (see FIG. 3) is set to the on state to make the machine into forced four-wheel drive. In the four-wheel drive mode, the left and right running wheels (for example, the left and right front wheels 10) rotate at the same rotational speed. In the four-wheel drive mode, for example, when the traveling wheels (front wheels 10) are stuck in the deep soil surface, the traveling vehicle body 2 can escape from the deep soil surface.

Control device 100 shifts to four-wheel drive mode based on an operation signal from remote control device 160 during execution of the automatic mode. As a result, for example, when the traveling vehicle body 2 is stuck in the deep soil surface during execution of the automatic mode, the four-wheel drive mode is executed by the operation from the remote control device 160 to forcibly switch to the four-wheel drive. , the traveling vehicle body 2 can be escaped from the depth of the soil surface.

<Remote control device>
Remote control device 160 will be described with reference to FIG. FIG. 7 is a front view showing remote control device 160. As shown in FIG. As described above, the remote control device 160 is capable of wireless communication with the control device 100 (see FIG. 3), and accepts an operation by the operator to change the running mode of the body (seedling transplanter 1). ), remotely control the aircraft, change the settings of the aircraft, and the like.

As shown in FIG. 7, the remote control device 160 includes a display section 86 (hereinafter referred to as a remote control side display section 86b) and a setting section 87 (hereinafter referred to as a remote control side operation section 87b).

The remote control side display section 86b is, for example, a liquid crystal screen, and displays an opening screen, a home screen (top screen), a driving mode switching screen (mode screen), a menu screen, a remote control setting screen, a pairing screen, and brightness of the liquid crystal screen. Displays the brightness adjustment screen to be adjusted, the power saving time adjustment screen, the remote control information screen, the ending screen, etc.

Note that the remote control side display section 86b is configured so that the screen is changed by operating various buttons of the remote control side operation section 87b, which will be described later, or by the elapse of time.

As shown in FIG. 7, the remote control side operation unit 87b includes a mode switching operation tool (running mode button) 8701 for switching between the automatic mode and the remote control mode, and a running vehicle body 2 (see FIGS. 1 and 2) during execution of the automatic mode. ), a four-wheel drive mode switching operation tool (forced four-wheel drive button) 8703, a return button 8704, a menu button 8705, and a decision button 8706. , a function button 8707, a start button 8709, a power button 8710, a stop operation tool (stop button) 8711 for stopping the autonomous running of the traveling vehicle body 2, and a temporary stop operating tool for temporarily stopping the autonomous traveling of the traveling vehicle body 2 ( pause button) 8712.

In this way, the remote controller side operation unit 87b has the mode switching operation tool (driving mode button) 8701 and the shift operation tools 8702 and 8708, so that the remote control device 160 can switch between the automatic mode and the remote operation mode. The remote control device 160 can be used to change the travel speed during execution of the remote control mode. Thereby, remote operability can be improved.

Further, since the remote control side operation unit 87b has a stop operation tool (stop button) 8711 and a temporary stop operation tool (pause button) 8712, the remote control device 160 can be used to control the traveling vehicle body during execution of the remote operation mode. You can stop and pause. Thereby, remote operability can be improved. In addition, by having a four-wheel drive mode switching operation tool (forced four-wheel drive button) 8703 in the remote control side operation unit 87b, when the traveling vehicle body 2 is stuck in the depth of the soil surface during execution of the automatic mode, the remote control device 160 By executing the four-wheel drive mode by the operation of , the traveling vehicle body 2 can be escaped from the depth of the soil surface.

Further, the remote controller side operation unit 87b can adjust the forward and backward movements of the traveling vehicle body 2 by means of the shift operation tools 8702 and 8708 during execution of the remote operation mode. Shift operation tools 8702 and 8708 increase the speed of the traveling vehicle body 2 and move the traveling vehicle body 2 forward. and a second shift operation tool (reverse button) 8708 for moving the vehicle body 2 backward.

In this way, the acceleration of the traveling vehicle body 2 and the forward movement of the traveling vehicle body 2 are performed by the forward button 8702, which is the same operation tool, and the deceleration of the traveling vehicle body 2 and the backward movement of the traveling vehicle body 2 are performed by the same operation tool, which is the reverse movement. Since it can be performed with a button, remote operability can be improved.

Further, the remote controller side operation unit 87b enables adjustment of the steering of the front wheels 10, which are the steered wheels, by the steering device 95 (see FIG. 3) during execution of the remote operation mode. Therefore, the remote control device 160 has a left steering operation tool for steering the front wheels 10 to the left and a right steering operation tool for steering the front wheels 10 to the right. In the example shown in FIG. 7, the left steering operation tool is a return button 8704 that is an operation tool for returning to the previous item among various setting items, and the right steering operation tool is for determining various setting items. It is a determination button 8706 which is an operation tool.

In this way, the right steering operation tool, which is an operation tool for steering the front wheels 10, which are steered wheels, to the right is provided with a function as an operation tool (determination button 8706) for determining various setting items, and the front wheels 10, which are steered wheels, are provided. By giving the left steering operation tool, which is an operation tool for left steering, a function as an operation tool (return button 8704) for returning to the previous item of various setting items, thereby reducing the types and numbers of the operation tools. , and the remote control device 160 can be simplified.

The remote control side display section 86b displays information as to whether or not the traveling vehicle body 2 (see FIGS. 1 and 2) is currently capable of autonomous traveling. Further, the remote control side display section 86b displays information as to whether the traveling vehicle body 2 is autonomously traveling. Further, the remote controller side display section 86b displays information as to whether or not the traveling vehicle body 2 can be remotely controlled at present. Furthermore, the remote controller side display section 86b displays information as to whether or not the traveling vehicle body 2 is being remotely controlled.

In this way, the remote controller side display section 86b displays information as to whether or not the traveling vehicle body 2 is currently autonomously traveling, whether it is currently autonomously traveling, whether it is currently remote controllable, and whether it is currently being remotely controlled. Therefore, the operator can easily grasp the information. Thereby, workability can be improved.

The above-mentioned information displayed by the remote control side display unit 86b (information indicating whether or not the traveling vehicle body 2 is currently autonomously traveling, whether it is currently autonomously traveling, whether it is currently remote controllable, and whether it is being remotely controlled). can also be displayed on the body-side display section 86a (see FIG. 3) that constitutes the display section 86 of the present embodiment together with the remote control-side display section 86b.

In addition, the remote controller side display section 86b displays information as to whether or not the teaching mode is being executed, and displays information as to whether or not the field information is being acquired. When the teaching mode is being executed and the field information is acquired, the remote control side display unit 86b displays a display indicating that the entire field can be driven autonomously, and autonomous driving and manual driving are possible within the field. Display the required display. Whether or not the teaching mode is being executed and whether or not the farm field information is being acquired is determined by the control device 100 (see FIG. 3).

In this way, the remote control side display unit 86b displays a display indicating that the entire field can be driven autonomously and a display indicating that autonomous driving and manual driving are required within the field. It is possible to easily grasp whether all autonomous driving is possible or whether autonomous driving and manual driving are required. Thereby, workability can be improved.

Note that the above information displayed by the remote control display unit 86b (information indicating whether the teaching mode is being executed, information indicating whether field information has been obtained, (Information on whether autonomous travel or manual travel is necessary) can also be displayed on the body-side display section 86a that constitutes the display section 86 of the present embodiment together with the remote control-side display section 86b.

Further, the remote controller side display section 86b displays the display of forward and backward movement of the traveling vehicle body 2 and the display of the steering angle of the steered wheels (front wheels 10) by the steering device 95 during execution of the remote control mode. In this case, the forward button 8702, which is the first shift operation tool, moves the traveling vehicle body 2 forward only while the forward button 8702 is being operated. Further, the reverse button 8708, which is the second shift operation tool, causes the traveling vehicle body 2 to move backward only while the reverse button 8708 is being operated. The decision button 8706, which is a right steering operation tool, steers the steering wheels (front wheels 10) to the right according to the operation amount (pressing time) of this decision button 8706, and the return button 8704, which is a left steering operation tool, steers this. The steering wheel (front wheel 10) is steered to the left according to the operation amount (pressing time) of the return button 8704 .

According to such a configuration, the operator can easily obtain operational feeling when moving forward and backward of the traveling vehicle body 2 and when steering the steered wheels (front wheels 10) left and right, thereby improving remote operability.

When the control device 100 (see FIG. 3) detects that the remote control device 160 has been powered off, the seedling transplanter 1 immediately stops and switches to the manual mode. Further, the controller 100 restricts the vehicle speed of the traveling vehicle body 2 from stopping from the 1st speed by the forward button 8702 or the reverse button 8708 during execution of the remote control mode. Further, when the traveling vehicle body 2 is temporarily stopped during execution of the remote control mode, the control device 100 restricts the traveling vehicle body 2 from shifting with the forward button 8702 or the reverse button 8708 . In this case, control device 100 accepts the operation signal of forward button 8702 or reverse button 8708 only when start button 8709 is pressed simultaneously.

Further, the control device 100 shifts (increases or decelerates) the traveling vehicle body 2 when the forward button 8702 or the reverse button 8708 is pressed simultaneously with the function button 8707 . Further, the control device 100 controls to sound a buzzer or the like when an operation signal from the remote control device 160 is received, and confirms communication between the machine (seedling transplanter 1, traveling vehicle body 2) and the remote control device 160. Execute.

Further, a function for editing the generated route displayed on the remote control side display section 86b or the display section 86 may be provided. Therefore, it is possible to deal with the case where the area acquisition method is incorrect. Also, in a field that can be approximated to a square on the generation path, when teaching is performed without planting two sides facing each other, the operation on the display unit 86 or the operation on the remote control device 160 automatically without a temporary stop. The configuration may be such that the side from which turning is started and the side from which turning is started by operating the remote control device 160 after pausing and moving the aircraft to a ridge by operating the remote control device 160 can be freely changed.

In addition, when teaching is carried out while driving around the entire perimeter of the field without planting, the operation on the display unit 86 or the operation on the remote control device 160 automatically starts turning without pausing, and It may be possible to freely change the side on which turning is started by operating the remote controller 160 after stopping and moving the aircraft to the ridge by operating the remote controller 160 . Also, the side that serves as a reference for the reciprocating process may be freely changeable.

Further, a function that enables turning to the next process by operating the remote control device 160 even during the reciprocating process may be provided. Therefore, automatic traveling is possible even in fields with obstacles. In addition, during the reciprocating process, during automatic planting travel, a configuration may be adopted in which reverse turning is started on the spot by performing an operation different from the operation of resuming automatic planting travel after pausing the machine body.

Further, a configuration may be adopted in which the position at which the vehicle is turned back on the spot is recognized as a ridge. Therefore, in the case of a deformed field, it is possible to cope with the case where turning is required at a position different from the turning position in the previous process.

<Display example on the remote controller display>
Display examples of the remote control side display section 86b (see FIG. 7) will be described with reference to FIGS. 8 to 16. FIG. 8 to 11 are diagrams showing display examples of the top screen on the remote control side display section 86b. 8 shows a display example of the teaching screen of the top screen, FIG. 9 shows a display example of the remote control screen of the top screen, and FIG. A display example of the running screen is shown, and FIG. 11 shows a display example of the manual running screen among the top screens.

FIG. 12 is a diagram showing a display example of a mode screen on the remote controller side display section 86b. 13 to 15 are diagrams showing display examples of menu screens on the remote control side display section 86b. FIG. 13 shows a display example of the function setting screen among the menu screens, and FIG. A display example of the attached section operation screen is shown, and FIG. 15 shows a display example of the seedling rail operation screen on which the operation of the spare seedling frame (seedling rail) 50 (see FIG. 1) is possible among the menu screens. FIG. 16 is a diagram showing an example of a screen display during teaching on the remote controller side display section 86b.

As shown in FIGS. 8A to 8D, the remote control display unit 86b displays the remaining battery level, the GNSS level as positioning means, and the communication connection state at the top of the teaching screen. The current mode (teaching mode) is displayed in the upper area below the upper area, the area determination information (work area information) and the current state are displayed in the middle area below the upper area, and the Various messages are displayed in the lower area.

As shown in FIGS. 9A to 9L, the remote control display unit 86b displays the remaining battery level, the GNSS level as positioning means, and the communication connection state at the top of the remote operation screen. The upper area below the upper area displays the current mode (remote operation mode), and the middle area below the upper area displays area determination information (work area information) and current status. In the lower area, the steering angle (steering angle) state and the state of the shift operating tool indicating the forward/reverse lever are displayed.

Note that, as shown in FIG. 9, in the steering angle display, arrows indicate the traveling direction of the aircraft. Also, in the steering angle state display, the steering angle of the front wheels 10 (see FIGS. 1 and 2), which are steering wheels, is displayed in three stages of "small", "large", and "maximum" using three types of icon displays. is displayed.

As shown in FIGS. 10A to 10H, the remote control display unit 86b displays the remaining battery level, the GNSS level as positioning means, and the communication connection state at the top of the automatic driving screen. The upper area below the upper area displays the current mode (automatic mode), the middle area below the upper area displays area confirmation information (work area information), the current state, and the lower area of the middle area. In the lower area of , the running state (“forward” or “neutral”), the state of the shift operation tool indicating the forward/reverse lever, and various messages are displayed.

As shown in FIGS. 11A to 11G, the remote control side display unit 86b displays the remaining battery level, the GNSS level as positioning means, and the communication connection state at the top of the manual running screen. The current mode (manual mode) is displayed in the upper area below the upper part, and the area determination information (work area information) and the possibility of switching to automatic mode are displayed in the lower area below the middle area. Various messages are displayed in the lower area below the middle area.

As shown in FIGS. 12A to 12H, the remote control side display unit 86b displays the remaining battery level, the GNSS level as positioning means, and the communication connection state at the top of the mode screen. The area below displays multiple menus. In the example shown in FIG. 12, the modes of "teaching", "automatic driving", "manual driving", and "remote control" are displayed below the currently opened item "drive mode switching". In the example shown in FIG. 12, below (at the bottom) of the mode items, as an explanation of the operation for determining the item, the operation button display icon of the remote control device 160 (see FIG. 7) and "Long Press Confirmation" are displayed. . By selecting and confirming a desired item from a plurality of menus displayed on the mode screen, the operator can proceed to the selected item.

As shown in FIGS. 13A to 13O, the remote controller display unit 86b displays the remaining battery level, the GNSS level as positioning means, and the communication connection state at the top of the function setting screen. In the lower area of the upper part, the currently opened item "function setting" and selection items ("seeding amount", "planting depth", "rotor height", etc.) are displayed, and displays the seedling collection amount display icon, the current value of the seedling collection amount, and the correction value of the seedling collection amount. Below that, the rotor height display icon, current rotor height value, and rotor height correction value are displayed. display the current value of the oil pressure sensitivity and the correction value of the hydraulic pressure sensitivity. Further, in the example shown in FIG. 13, at the bottom, as an operation explanation for adjusting the seedling amount, planting depth, rotor height, and hydraulic sensitivity adjustment, the operation button display icon of the remote control device 160 and "long press enter" are displayed. are doing.

As shown in FIGS. 14 (A) to (H), the remote control side display unit 86b displays the remaining battery level, the GNSS level as the positioning means, and the communication connection state at the top of the planting unit operation screen. , in the area below the top, the currently open item "planting" is displayed, and below it, "raise planting section" selected when raising the seedling planting section 4 is displayed. Below that, "planting section down" selected when descending the seedling planting section 4 is displayed, and below that, the on/off state of "planting" is displayed. In addition, in the example shown in FIG. 14 , “Long Press Enter” is displayed together with the operation button display icon of the remote control device 160 as an operation explanation of the seedling planting section 4 at the bottom.

As shown in FIGS. 15A and 15B, the remote control side display unit 86b displays the remaining battery level, the GNSS level as the positioning means, and the communication connection state at the top of the seedling rail operation screen, In the area below the top, the currently open item "seedling rail" is displayed, and below it, "extend" selected when extending the spare seedling frame (seedling rail) 50 is displayed. , and below it, "Shrink" selected when shrinking the spare seedling frame (seedling rail) 50 is displayed. Further, in the example shown in FIG. 15, as an explanation of the operation of the spare seedling frame (seedling rail) 50, the operation button display icon of the remote control device 160 is displayed together with the message "operating during depression" at the bottom.

As shown in FIG. 16, the remote control side display unit 86b displays the remaining battery level, the GNSS level as the positioning means, and the communication connection at the top of the screen during teaching of the traveling vehicle body 2 (see FIGS. 1 and 2). On the menu screen displaying the status, the "menu" column below it, and the "function setting", "seedling rail", "planting part", and "remote control setting" in order from the top below it, select "remote control setting ” is selected. Further, in the example shown in FIG. 16 , “Select” is displayed together with the operation button display icon of the remote control device 160 as an operation explanation of menu selection at the bottom.

Further, the remote control side display section 86b displays an interrupt screen that is preferentially displayed when each section is in a predetermined state. The interrupt screen displays, for example, the status of each part, a message, and "OK" to be selected when the operator confirms the status.

As an example of the display on the interrupt screen, for example, when the traveling vehicle body 2 is "tilted and stopped", a message such as "the machine body is greatly tilted and will stop" is displayed. In addition, for example, when the traveling vehicle body 2 becomes "automatic travel stop", "running will be temporarily stopped because the state of GNSS has deteriorated", "parking brake pedal is applied", "running will be temporarily stopped" message such as "The vehicle will stop running due to an abnormal condition detected", "The vehicle has detected an obstacle and has stopped temporarily", or "Please check safety".

Also, for example, when the battery level is low, a message such as "Please replace the battery" is displayed. Also, for example, in the case of "teaching", messages such as "sub-route created" and "deleted acquired points" are displayed. For example, in the case of "mode switching", messages such as "switched to manual driving", "switched to automatic driving", "switched to remote control mode", "switched to teaching mode", etc. is displayed.

<Example of display on machine side display>
Display examples of the body-side display section 86a will be described with reference to FIGS. 17 to 28. FIG. 17 to 28 are diagrams showing display examples of screens on the device-side display section 86a. The seedling transplanter 1 (see FIGS. 1 and 2) also displays various information on the body-side display section 86a of the control section 41 (see FIGS. 1 and 2).

As shown in FIG. 17, the fuselage-side display unit 86a includes a display icon 8601 for the GNSS level as positioning means, a display icon 8602 for the robot mode (automatic mode) switching state, a display icon 8603 for the remote control connection state, and a work icon 8603. An area information acquisition state display icon 8604, a mode display icon 8605, and a mode state display icon 8606 are displayed.

In addition, the machine body side display section 86a displays adjusted values (information) of each section including the seedling planting section 4 (see FIGS. 1 and 2) during execution of any one of the automatic mode, the remote control mode and the manual mode. display. Specifically, the body-side display unit 86a displays the speed of the traveling body 2 (see FIGS. 1 and 2), seedling planting, and speed adjusted during execution of any one of the automatic mode, the remote control mode, and the manual mode. The seedling amount and seedling planting depth in the section 4, the oil pressure sensitivity in the seedling planting section 4, and the height of the leveling rotor 63 (see FIG. 1) are displayed. Further, the body-side display section 86a displays the number of times the seedling mats are laterally fed in the seedling planting section 4 and the number of seedling mats required per 10 ares. As shown in FIG. 17, the body side display section 86a displays the number of seedling mats required per 10 ares on the upper left side, the amount of seedlings collected in the seedling planting section 4 on the middle left side, and the number of seedlings on the lower left side. The number of times the seedling mat is laterally fed in the planting section 4 is displayed, the seedling planting depth in the seedling planting section 4 is displayed on the upper right side, the height of the leveling rotor 63 is displayed on the middle right side, and the seedling planting is displayed on the lower right side. Hydraulic sensitivity in section 4 is displayed.

In this way, by displaying the adjusted values of each part including the seedling planting part 4 during execution of any one of the automatic mode, the remote control mode and the manual mode on the body side display part 86a, the operator can can easily grasp the adjusted value of . Thereby, workability can be improved. In addition, the speed of the traveling vehicle body 2, the amount of seedlings taken and the planting depth in the seedling planting unit 4, which are adjusted during the execution of any one of the automatic mode, the remote control mode, and the manual mode, on the machine body side display unit 86a. By displaying the values of the hydraulic pressure sensitivity in the seedling planting unit 4 and the height of the ground leveling rotor 63, the operator can easily grasp these adjusted values. Thereby, workability can be improved.

In addition, by displaying the number of times the seedling mats are laterally fed in the seedling planting section 4 and the number of seedling mats required per 10 ares on the body side display section 86a, the operator can easily grasp these information. can be done. Thereby, workability can be improved.

Further, as shown in FIG. 18, when the connection with the remote control device 160 (see FIG. 7) is disconnected, the device-side display unit 86a does not display the remote control connection state display icon 8603 (displays it in a darkened state). do).

Further, as shown in FIG. 19, the machine body side display unit 86a displays a mode display icon 8605 when the automatic mode is being executed, and as shown in FIG. In this case, the mode display icon 8605 is displayed in a darkened state, and the display content is changed.

In addition, as shown in FIG. 21, when the area confirmation information (work area information) is acquired, the body side display unit 86a displays a display icon 8604 indicating the work area information acquisition state, and Thus, when the area determination information (work area information) has been acquired, the display icon 8604 indicating the work area acquisition status is not displayed (displayed in a darkened state). Furthermore, as shown in FIG. 23, the machine-side display unit 86a changes the display icon 8604 of the work area information acquisition status when the area determination information (work area information) indicating that the farm field has an irregular shape has been acquired. Change and display the display contents.

Further, as shown in FIG. 24, when the traveling vehicle body 2 is autonomously traveling, that is, when the automatic mode is being executed, the body-side display unit 86a displays a mode display icon 8605, and displays a mode display icon 8605 as shown in FIG. 26, when the traveling vehicle body 2 is in a state in which autonomous travel is possible, the mode display icon 8605 is displayed by changing the display content, and as shown in FIG. , the display icon 8605 of the mode is darkened and displayed, and the display contents are changed.

In addition, as shown in FIG. 27, the body side display section 86a displays a screen for adjusting the seedling amount. 27 is displayed by switching from the main screen shown in FIG. 17 or the like. In addition, the body side display section 86a displays a screen for adjusting the planting depth, as shown in FIG. The screen for adjusting the planting depth shown in FIG. 28 is displayed by switching from the main screen shown in FIG. 17 or the like.

<Another example of acquiring work area information>
FIG. 29 is a diagram showing another example of work area information acquisition in the teaching mode. As shown in FIG. 29, in another example of work area information acquisition in the teaching mode, the control device 100 (see FIG. 3) operates the remote control device 160 (see FIG. 7) or operates the seedling transplanter 1 side. Among the positional information Pa ₁ to Pa ₄ of the points acquired in the process of recognizing the work area, the latest one (positional information Pa ₄ ) is erased one by one.

In the past, there was no way to correct an error in work area recognition during work area recognition work, and the only way was to reset the acquired work area information. Corrections can be made during work area recognition.

Further, the location information _Pa4 of the point acquired in the process of recognizing the work area may be deleted by pressing at least two or more operation buttons of the remote control device 160 at the same time. By configuring in this way, erroneous operations can be prevented. Further, for example, by pressing a dedicated button on the side of the seedling transplanter 1, a screen for confirming the location information of the location is displayed on the body side display unit 86a (see FIG. 3), and the location acquired in the process of recognizing the work area is displayed. The position information _Pa4 may be deleted by using a jog dial or the like while the confirmation information screen is displayed. By configuring in this way, erroneous operations can be prevented.

<Standing steering assist mechanism>
30 and 31 are diagrams showing the standing steering assist mechanism. In the seedling transplanter 1, for example, when the seedling tank 53 (see FIGS. 1 and 2) is loaded with seedlings, the operator may stand on the floor step 33 and steer. As shown in FIG. 30, the floor step 33 is provided with a recessed portion 33a for the worker to put his or her foot into, so that the worker standing and steering can stand on the floor step 33, thereby enhancing safety.

Further, as shown in FIG. 31, by providing a guard portion 33b standing on the floor step 33 and guarding the waist of the worker at the tip portion, the worker can be shaken off the body (seedling transplanter 1). can be prevented, and safety can be improved.

Further, as shown in FIG. 32, a configuration in which the wheels 10 and 11 are driven by the motor M may be employed. The motor M is driven by a battery BT mounted on the aircraft.

The battery BT is mounted on the floor step 33, and the motor M is positioned below the body. By equipping a battery with a large capacity, it is possible to increase the work time that can be performed with one charge, but there is a problem that the weight becomes heavy, and there is a concern that the mounting space and the traveling stability and running performance of the aircraft will decrease. be done.

Therefore, the weight can be reduced by not mounting the generator EG for generating the battery BT on the airframe. Also, in a machine such as a seedling transplanter that periodically replenishes seedlings and fertilizer and stops at the edge of a ridge, the battery may be downsized considering that there is a timing at which it can be charged.

By reducing the size of the battery BT, it is possible to improve the weight, which is a concern in motor driving.

The generator EG is configured to be movable so that the battery BT can be charged when replenishing seedlings and fertilizer. In addition, a connector ZP is provided on the front side of the fuselage for charging the battery BT by the generator EG so that the fuselage can be stopped facing forward on the ridge and charging work can be done from the front of the fuselage for replenishment work. Also good. In particular, it is good to have it around the hood and inside the hood cover. Therefore, when replenishing seedlings or fertilizer, the charging plug of the generator can be easily inserted into the connector ZP.

Also, the capacity of the battery BT must be the minimum required for charging until the seedlings placed in the seedling tank are exhausted from the fully charged state.

Moreover, it is good also as a structure which mounts the generator EG on an airframe. In that case, the generator EG is an internal combustion engine, and may be configured to operate when charging is required and to stop when the charging capacity reaches a sufficient amount.

Further effects and modifications can be easily derived by those skilled in the art. Therefore, the broader aspects of the invention are not limited to the specific details and representative embodiments so shown and described. Accordingly, various changes may be made without departing from the spirit or scope of the general inventive concept defined by the appended claims and equivalents thereof.

1 Work vehicle (seedling transplanter)
2 traveling vehicle body 4 work machine (seedling planting section)
10 running wheels (steering wheels, front wheels)
11 running wheel (rear wheel)
M Motor BT Battery EG Generator ZP Connector

Claims (4)

a traveling vehicle body having traveling wheels including steering wheels and capable of traveling in a field;
Equipped with a planting device for planting seedlings in the field,
A seedling transplanter having a traveling vehicle body with a motor for driving a traveling wheel and a battery for driving the motor. 2. The seedling transplanter according to claim 1, further comprising a generator for charging said battery, wherein said generator is not mounted on the traveling vehicle body. 3. The seedling transplanter according to claim 1, wherein a connector for charging said battery is provided on the front side of the traveling vehicle body. 4. The seedling transplanter according to any one of claims 1 to 3, wherein the generator can charge the running vehicle body that is stopped at the edge of a ridge.

Images