JP7044477B2 - Automatic steering control device - Google Patents

Description

The present invention relates to an automatic steering control device for performing ground work with a work device of a work vehicle .

In the conventional work vehicle, the position information of the work start position and the work end position is automatically acquired when the work device is turned on and off, and the reference line is created from the automatically acquired work start position and work end position. , Some include an automatic steering device that automatically steers the steering wheel along this reference line to allow the aircraft to travel straight (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2016-21890

In such a conventional work vehicle, since the position where the work device is turned on and off can be acquired as the work start position and the work end position, it is not necessary to acquire the work start position and the work end position, and the operability is operability. Has the advantage of being good.

However, if the work device is turned on or off due to an erroneous operation, the work start position or work end position may be acquired at a position different from the position where the work start position or work end position should be acquired. .. In this case, it is necessary to re-establish the reference line with another work line, and during that time, the automatic steering device cannot be used, and there is a problem that highly accurate work running cannot be performed.

Further, in order to acquire the position where the work device is turned on / off as the work start position or the work end position, a detection member for detecting the on / off of the work device is required, so that the number of parts constituting the machine body increases. There's a problem.

In consideration of the above-mentioned conventional problems, it is an object of the present invention to provide a work vehicle capable of preventing a reference position for straight running from being acquired by an erroneous operation and suppressing an increase in the number of parts. ..

The first aspect of the present invention is a working device (4,62C, 63) attached to the vehicle body (2).
The steering member (35) that steers the vehicle body (2) and
A position information acquisition device (200) that acquires the position information of the vehicle body (2), and
A user instruction member (207) that receives a user instruction for acquiring reference position information used when the vehicle body (2) goes straight, and a user instruction member (207).
A straight-ahead device (205) that operates the steering member (35) so as to make the vehicle body (2) go straight.
A control device (100) that executes automatic straight-ahead control for causing the straight-ahead device (205) to operate the steering member (35) based on the reference position information.
Equipped with
The control device (100) calculates a straight reference line (R) and a single or a plurality of straight target lines (T) parallel to the straight reference line (R) based on the reference position information, and performs wireless communication. By using this, the straight reference line (R) and the straight target line (T) can be displayed on the external information terminal (1000) mounted on the vehicle body (2).
The notification device (208) is activated to notify that the vehicle body (2) is close to the field edge and the automatic straight-ahead control needs to be terminated , but even if the notification device (208) is activated. If the automatic straight-ahead control cannot be terminated, the vehicle body (2) will move forward when the vehicle body (2) travels forward for a predetermined distance or a predetermined time after the notification device (208) is activated. It is automatically decelerated, and after the start of automatic deceleration, abrupt deceleration is performed once or multiple times at predetermined time intervals .
If an operation to stop traveling is detected while the automatic straight-ahead control is being executed, the control device (100) does not reflect the steering operation of the steering member (35), or the steering member (35). ) Is stopped, but the straight-ahead device (205) is not stopped even when the traveling is stopped.
In the second aspect of the present invention, the reference position information includes the first reference position information corresponding to the first reference point (A) at which the straight reference line (R) starts and the second reference position information at which the straight reference line (R) ends. The second reference position information corresponding to the reference point (B), and
When the first reference position information is acquired, the traveling locus (L) of the vehicle body (2) is displayed on the external information terminal (1000).
The first automatic steering control device of the present invention is characterized in that when the second reference position information is acquired, the straight target line (T) is displayed on the external information terminal (1000).
A third aspect of the present invention is a work clutch (66) that turns on and off the power transmitted to the work device (63).
A work clutch sensor (209) for detecting an on / off state of the power transmitted to the work device (63) is provided.
The traveling locus (L) is displayed on the external information terminal (1000) when the on state of the power transmitted to the working device (63) is detected by the working clutch sensor (209). The second automatic steering control device of the present invention is characterized by this.
In the fourth aspect of the present invention, the external information terminal (1000) has a traveling map program for displaying the straight reference line (R) and the straight target line (T), and a field for displaying the depth of the field. A management application is installed that allows a predetermined program to be selected from the depth map program and the material spray amount map program for displaying the spray amount of the material to be sprayed on the field. The automatic steering control device according to any one of the first to third aspects of the present invention, characterized in that a map corresponding to the program is displayed.
In the fifth aspect of the present invention, the control device (100) has a predetermined steering member operation mode selected from a plurality of steering member operation modes related to the operation of the steering member (35) by the straight-ahead device (205). The automatic straight-ahead control is executed according to
The automatic steering control device of the present invention according to any one of the first to fourth aspects, wherein the selection of the steering member operation mode is manually performed according to a user instruction.
In the sixth aspect of the present invention, the straight-ahead device (205) has a steering step motor (206) that operates with a motor operating amount corresponding to an input pulse signal.
The control device (100) is characterized in that it executes control for stopping the straight-ahead device (205) when the deviation of the motor operating amount with respect to the input pulse signal exceeds a predetermined level. The automatic steering control device of the present invention according to any one of 1 to 5.
The first invention related to the present invention includes a working device (4,62C, 63) attached to a vehicle body (2), a steering member (35) for steering the vehicle body (2), and the vehicle body (2). The position information acquisition device (200) for acquiring the position information of the vehicle body, the user instruction member (207) for receiving the user instruction for acquiring the reference position information used when the vehicle body (2) goes straight, and the vehicle body. A straight-ahead device (205) that operates the steering member (35) so as to make the (2) go straight, and an automatic operation for causing the straight-ahead device (205) to operate the steering member (35) based on the reference position information. A control device (100) for executing straight-ahead control is provided, and the control device (100) is a single unit parallel to a straight-ahead reference line (R) and a straight-ahead reference line (R) based on the reference position information. A plurality of straight target lines (T) are calculated, and the straight reference line (R) and the straight target line (T) are mounted on the external information terminal (1000) mounted on the vehicle body (2) by using wireless communication. ) Is an automatic steering control device characterized by being able to display.

In the second invention related to the present invention, the reference position information includes the first reference position information corresponding to the first reference point (A) where the straight reference line (R) starts, and the straight reference line (R). The second reference position information corresponding to the second reference point (B) ending in), and when the first reference position information is acquired, the traveling locus (L) of the vehicle body (2) becomes the external information. A second aspect of the present invention, which is displayed on the terminal (1000) and, when the second reference position information is acquired, the straight target line (T) is displayed on the external information terminal (1000). 1 is the automatic steering control device of the present invention .

A third aspect of the present invention relates to a work clutch (66) that turns on / off the power transmitted to the work device (63), and detects an on / off state of the power transmitted to the work device (63). The work clutch sensor (209) is provided, and the travel locus (L) is when the on state of the power transmitted to the work device (63) is detected by the work clutch sensor (209). The second invention is an automatic steering control device according to the present invention, which is displayed on the external information terminal (1000).

A fourth invention related to the present invention is characterized in that the control device (100) takes into account work device information regarding the work device (4) when calculating the straight target line (T). It is an automatic steering control device of any 1st to 3rd invention which is related to this invention .

In the fifth aspect of the present invention, the external information terminal (1000) is provided with a travel map program for displaying the straight reference line (R) and the straight target line (T), and the depth of the field. A management application that can select a predetermined program from the field depth map program for displaying and the material spraying amount map program for displaying the spraying amount of the material to be sprayed on the field is installed. The automatic steering control device according to any one of the first to fourth inventions according to the present invention, characterized in that a map corresponding to the selected predetermined program is displayed.

In a sixth aspect of the present invention, the control device (100) is a predetermined control device (100) selected from a plurality of steering member operation modes related to the operation of the steering member (35) by the straight-ahead device (205). A first to fifth aspect of the present invention, wherein the automatic straight-ahead control according to the steering member operation mode is executed, and the selection of the steering member operation mode is manually performed according to a user instruction. It is an automatic steering control device of any of the inventions .

According to a seventh aspect of the present invention, the straight-ahead device (205) has a steering step motor (206) that operates with a motor operating amount corresponding to an input pulse signal, and the control device (100) has a control device (100). The first to first aspect of the present invention, wherein the control for stopping the straight traveling device (205) is executed when the deviation of the motor operating amount with respect to the input pulse signal exceeds a predetermined level. The automatic steering control device according to any one of the inventions of 6.

According to the present invention, a straight reference line (R) and a single or a plurality of straight target lines (T) parallel to the straight reference line (R) are calculated based on the reference position information, and the vehicle body (T) is used by wireless communication. Since the straight reference line (R) and the straight target line (T) can be displayed on the external information terminal (1000) mounted on 2), it is possible to prevent the reference position for straight running from being acquired by erroneous operation. At the same time, it is possible to suppress an increase in the number of parts.
According to the first invention related to the present invention, a straight reference line (R) and a single or a plurality of straight target lines (T) parallel to the straight reference line (R) are calculated based on the reference position information, and the radio is used. Since the straight reference line (R) and the straight target line (T) can be displayed on the external information terminal (1000) mounted on the vehicle body (2) by using communication, the reference position for straight running can be erroneously operated. It is possible to prevent it from being acquired in the above, and it is possible to suppress an increase in the number of parts.

According to the second invention related to the present invention, in addition to the effect of the first invention related to the present invention, when the first reference position information is acquired, the traveling locus (L) of the vehicle body (2) becomes. It is displayed on the external information terminal (1000), and when the second reference position information is acquired, the straight target line (T) is displayed on the external information terminal (1000), so that it is possible to promote the convenience of work. Is.

According to the third invention related to the present invention, in addition to the effect of the second invention related to the present invention, the traveling locus (L) is operated by the on state of the power transmitted to the working device (63). When it is detected by the clutch sensor (209), it is displayed on the external information terminal (1000), so that it is possible to promote the optimization of work.

According to the fourth invention related to the present invention , in addition to the effect of any one of the first to third inventions related to the present invention, when calculating the straight-ahead target line (T), the working apparatus (4). ) Is added, so it is possible to promote the optimization of the displayed information.

According to the fifth invention related to the present invention , in addition to the effect of any one of the first to fourth inventions related to the present invention, a map corresponding to the selected predetermined program is displayed. It is possible to promote the enhancement of displayed information.

According to the sixth invention related to the present invention , in addition to the effect of any one of the first to fifth inventions related to the present invention, the selection of the steering member operation mode is manually performed according to the user's instruction. Therefore, it is possible to promote high-precision work.

According to the seventh invention related to the present invention , in addition to the effect of any one of the first to sixth inventions related to the present invention, the deviation of the motor operating amount with respect to the input pulse signal exceeds a predetermined level. Occasionally, control is performed to stop the straight-ahead device (205), so that it is possible to promote work safety.

Side view of the seedling transplanting machine of the embodiment of the present invention Top view of the seedling transplanting machine of the embodiment of the present invention Top view of the main part of the traveling vehicle body according to the embodiment of the present invention. Rear view of the main part of the control unit including the handle according to the embodiment of the present invention. (A) Rear view of the main part showing the configuration of the automatic steering device of the steering wheel according to the embodiment of the present invention, (b) Side view of the main part showing the configuration of the automatic steering device of the steering wheel according to the embodiment of the present invention. A block diagram showing members related to various controls according to the embodiment of the present invention. A flowchart showing a control for correcting the acquired position coordinates of the embodiment of the present invention according to the inclination of the machine body and the like. A flowchart showing automatic straight-ahead control by the automatic steering device according to the embodiment of the present invention. A flowchart showing the acquisition of the first and second reference positions by the operation of the automatic straight-ahead setting member according to the embodiment of the present invention and the on / off of the automatic straight-ahead control. A flowchart showing an operation of erasing the first reference position and the second reference position according to the embodiment of the present invention. A flowchart showing a control for erasing the first reference position by operating the steering wheel after acquiring the first reference position according to the embodiment of the present invention. Schematic diagram of work showing a first reference position, a second reference position, and a reference line according to an embodiment of the present invention and showing a target position. A flowchart showing the operation of the notification device according to the embodiment of the present invention and the automatic deceleration control when the stop operation of the automatic steering device is not performed after the notification device is operated. A flowchart showing a control for erasing a first reference position, a second reference position, and a reference line by running on a headland in a field according to an embodiment of the present invention. (A) Explanatory drawing of the time-dependent display of the straight reference line, the straight target line, and the traveling locus on the tablet terminal of the seedling transplanter according to the embodiment of the present invention (No. 1), (b) The embodiment of the present invention. Explanatory drawing of the time-dependent display of the straight reference line, the straight target line and the traveling locus on the tablet terminal of the seedling transplanter (No. 2), (c) The straight reference line on the tablet terminal of the seedling transplanter according to the embodiment of the present invention. , Explanatory drawing of time-lapse display of straight-ahead target line and travel locus (No. 3), (d) Time-lapse of straight-ahead reference line, straight-ahead target line and travel locus in the tablet terminal of the seedling transplanter according to the embodiment of the present invention. Explanatory drawing of the display (No. 4), (e) Explanatory drawing of the time-dependent display of the straight reference line, the straight target line, and the traveling locus in the tablet terminal of the seedling transplanting machine according to the embodiment of the present invention (No. 5). Explanatory drawing of automatic straight running of seedling transplanting machine of embodiment of this invention Explanatory drawing of automatic straight running of seedling transplanting machine of another embodiment (No. 1) of this invention Partial front view of the vicinity of the steering actuator of the seedling transplanting machine according to the embodiment of the present invention. (A) Plan view of the seedling transplanting machine according to another embodiment (No. 2) of the present invention, (b) Side view of the seedling transplanting machine according to another embodiment (No. 2) of the present invention. (A) Plan view of the seedling transplanting machine according to another embodiment (No. 3) of the present invention, (b) Side view of the seedling transplanting machine according to another embodiment (No. 3) of the present invention. Side view of the seedling transplanting machine of another embodiment (No. 4) in the present invention.

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

First, the basic configuration and operation of the seedling transplanting machine of the present embodiment will be described with reference to FIGS. 1 to 14.

FIG. 1 is a side view of the seedling transplanting machine according to the embodiment of the present invention. FIG. 2 is a plan view of the seedling transplanting machine according to the embodiment of the present invention. FIG. 3 is a plan view of a main part of the traveling vehicle body 2 according to the embodiment of the present invention. FIG. 4 is a rear view of a main part of the control unit including the handle 35 according to the embodiment of the present invention. FIG. 5A is a rear view of a main part showing the configuration of the automatic steering device 205 of the handle 35 according to the embodiment of the present invention, and FIG. 5B is an automatic steering device of the handle 35 according to the embodiment of the present invention. It is a side view of the main part which shows the structure of 205. FIG. 6 is a block diagram showing members related to various controls according to the embodiment of the present invention. FIG. 7 is a flowchart showing a control for correcting the acquired position coordinates of the embodiment of the present invention according to the inclination of the machine body and the like. FIG. 8 is a flowchart showing automatic straight-ahead control by the automatic steering device 205 according to the embodiment of the present invention. FIG. 9 is a flowchart showing the acquisition of the first and second reference positions A and B by the operation of the automatic straight-ahead setting member 207 according to the embodiment of the present invention, and the on / off of the automatic straight-ahead control. FIG. 10 is a flowchart showing an erasing operation of the first reference position A and the second reference position B according to the embodiment of the present invention. FIG. 11 is a flowchart showing a control for erasing the first reference position A by operating the steering wheel after acquiring the first reference position according to the embodiment of the present invention. FIG. 12 is a schematic diagram of an operation showing a first reference position A, a second reference position B, and a reference line R according to an embodiment of the present invention, and showing a target position. FIG. 13 is a flowchart showing the operation of the notification device 208 according to the embodiment of the present invention and the automatic deceleration control when the automatic steering device 205 is not stopped after the notification device 208 is operated. FIG. 14 is a flowchart showing a control for erasing the first reference position A, the second reference position B, and the reference line R by running on the headland of the field according to the embodiment of the present invention.

The reference line is also called a straight reference line to make the meaning easier to understand. The first reference position is also called the first reference point, and the second reference position is also called the second reference point.

The seedling transplanting machine of the present embodiment is an example of the working vehicle of the present invention.

The traveling vehicle body 2 is an example of the vehicle body of the present invention. The working device 4, the center float 62C, and the ground leveling rotor 63 are all examples of the working device of the present invention. The steering wheel 35 is an example of the steering member of the present invention. The GPS antenna 200 is an example of the position information acquisition device of the present invention. The automatic straight-ahead setting member 207 is an example of the user-instructed member of the present invention. The automatic steering device 205 is an example of the straight-ahead device of the present invention. The control device 100 is an example of the control device of the present invention. The tablet terminal 1000 is an example of the external information terminal of the present invention.

The leveling clutch 66 is an example of the working clutch of the present invention. The work detection sensor 209 is an example of the work clutch sensor of the present invention.

The steering actuator 206 is an example of the steering step motor of the present invention.

In this case, in the plan view, the left side with respect to the traveling direction of the aircraft is referred to as one side of the left and right sides of the aircraft, and the right side with respect to the traveling direction of the aircraft is referred to as the other side of the left and right sides of the aircraft. The details of each part will be described in detail below.

The passenger-type rice transplanter disclosed in FIG. 2 as an embodiment of the working machine of the present invention has an eight-row planting configuration, but this configuration may be used for a rice transplanter having a different number of planting rows. .. As shown in FIGS. 1 and 2, the rice transplanter takes seedlings from the seedling tank 53 via the elevating link device 3 on the rear side of the traveling vehicle body 2, and uses a plurality of seedling planting devices 55 ... to plant seedlings in the field. A work device 4 such as a seedling planting section for planting, a sowing device for supplying seeds, or a rotary for cultivating a field is provided so as to be able to move up and down, and a main body portion of the fertilizer application device 5 is arranged on the upper rear side of the traveling vehicle body 2. There is.

First, the main frame 15 constituting the traveling vehicle body 2 will be described.

As shown in FIG. 3, the main frame 15 includes a front beam frame 16 at the front of the machine body, a rear beam frame 17 at the rear of the machine body, and a central beam frame between the front and rear of the front beam frame 16 and the rear beam frame 17. 18 is provided, and the front beam frame 16 and the center beam frame 18 are connected by a pair of left and right front connecting frames 19 and 19, and the center beam frame 18 and the rear beam frame 17 are connected by a pair of left and right rear connecting frames 20. Connect at 20.

The front beam frame 16, the center beam frame 18, and the rear beam frame 17 have a longitudinal direction in the left-right direction, and the front connecting frame 19 and the rear connecting frame 20 have a longitudinal direction in the front-rear direction.

The left and right spacing between the left and right front connecting frames 19 and 19 and the rear connecting frames 20 and 20 are substantially the same. Further, the left-right lengths of the central beam frame 18 and the rear beam frame 17 are longer than the left-right lengths of the front beam frame 16. Since the left and right front connecting frames 19 and 19 and the rear connecting frames 20 and 20 are welded at the lower part of the central beam frame 18, the left and right front connecting frames 19 and 19 and the rear connecting frames 20 and 20 are connected. It may be composed of an integral metal square timber.

The driving force is transmitted to the left and right front wheels 10, 10, the rear wheels 11, 11, the working device 4, and the like in the space formed by the front beam frame 16, the center beam frame 18, and the left and right front connecting frames 19, 19. A transmission case 13 and a hydraulic continuously variable transmission (HST) 14 that outputs the driving force supplied from the engine 30 to the mission case 13 are provided.

Then, the left and right lifting frames 21 and 21 are provided at the rear portion of the rear beam frame 17 so as to project rearward at a space narrower than the left and right spacing of the left and right rear connecting frames 20 and 20, and the left and right lifting frames 21 and 21 are held. The rear support frame 22 is attached to the lower part of the upper frames 21 and 21.

Rear wheel transmission cases 11a and 11a for driving the left and right rear wheels 11 and 11 of the traveling vehicle body 2 are provided on both left and right sides of the rear support frame 22, and the elevating link mechanism is provided on the upper portion of the rear support frame 22. The left and right link frames 23, 23 that support 3 are provided so as to face upward.

The elevating link mechanism 3 is provided with a pair of left and right lower link arms 24, 24 on the lower side of the left and right link frames 23, 23 and between the left and right, and an elevating cylinder 25 is provided between the left and right lower link arms 24, 24. And an upper link arm 26 is provided above the elevating cylinder 25. The left and right lower link arms 24 and 24, the elevating cylinder 25, and the upper link arm 26 on the opposite side of the traveling vehicle body 2 are mounted on the front side of the work device 4.

Further, front transmission cases 10a and 10a that transmit to the left and right front wheels 10 and 10 of the traveling vehicle body 2 are provided on the front of the left and right ends of the central beam frame 18 and on the left and right outside of the left and right front connecting frames 19 and 19, respectively. At the same time, the left and right ends of the central beam frame 18 and the rear beam frame 17 are connected by the left and right extension frames 27 and 27, respectively. The left and right extension frames 27, 27 have a longitudinal direction in the front-rear direction.

Further, a central connecting frame 28 in the front-rear direction is provided below the central beam frame 18, the rear beam frame 17, and the rear support frame 22, and between the front and rear of the central beam frame 18 and the rear beam frame 17, and left and right rear portions. Front and rear support plates 29 and 29 for supporting the engine 30 are provided between the left and right of the connecting frames 20 and 20.

The front and rear support plates 29, 29 are provided with receiving plates 29a ... For receiving the engine 30 on both the left and right sides of the central connecting frame 28.

The left and right auxiliary frames 31, 31 that pass under the rear beam frame 17 and project rearward are provided on the left and right sides of the front and rear support plates 29, 29, and the rear portions of the left and right auxiliary frames 31, 31 are provided. Are connected by a rear auxiliary frame 32 in the left-right direction. The rear ends of the left and right auxiliary frames 31, 31 are connected to the left and right rear wheel transmission cases 11a, 11a.

As described above, the mainframe 15 is configured. Of the main frame 15, the floor on which the operator boardes the front-rear width from the front beam frame 16 to the rear beam frame 17, and the left-right width of the left and right front connection frames 19, 19 and the rear connection frames 20, 20. Cover with step 33. The floor tape 33 is integrally formed to improve the strength or reduce the number of parts, or it is configured to be separable on the front side and the rear side, and on the left side and the right side, respectively, so that it can be easily attached and detached.

In the above, as shown in FIG. 3, the periphery of the left and right side ends of the central beam frame 18 and the rear beam frame 17 and the left and right extension frames 27 and 27 are not covered by the floor step 33 and are exposed. At this time, the floor step 33 may be expanded to cover the entire main frame 15, but the floor step 33 may be shared among the aircraft having different sizes and number of planting work rows. The left and right extension steps 34 and 34 are arranged on both the left and right sides of the above.

With the above configuration, since the main frame 15 is configured by connecting a plurality of frame configurations, the strength is improved as compared with the conventional case.

Further, by arranging the central connecting frame 28 under the front and rear support plates 29 and 29 on which the engine 30 is mounted and connecting the front and rear support plates 29 and 29 with the left and right rear auxiliary frames 32 and 32, a heavy object is used. The engine 30 can be firmly held.

On the front side of the traveling vehicle body 2, as shown in FIGS. 1 and 2, a steering wheel 35 for steering the aircraft, a speed change operating lever 36 for operating the continuously variable transmission 14 and the working device 4, and traveling transmission of the traveling vehicle body 2 are on the front side. A bonnet 39 having an auxiliary shift operation lever 37 for operating the auxiliary shift change switching device (not shown) and a control panel 38 for operating each part of the machine body is provided. A front cover 40 that can be opened and closed is provided on the front side of the bonnet 39, and inside the front cover 40, a fuel tank, a battery, the left and right front wheels 10 and 10 for steering the handle 35, and left and right front wheel transmission cases are provided. An interlocking mechanism (not shown) that rotates the lower side of 10a and 10a is installed.

Further, in front of the front cover 40, various information such as the work state of the work device 4, the reduction of work materials consumed during the work, and the operation and non-operation of the automatic steering device 205, which will be described later, are lit by LEDs or the like. A center mascot 70 to be displayed is provided. The center mascot 70 is composed of a work display unit 71 arranged on the lower side of the machine body and on the rear side of the machine body, and an automatic straight display part 72 arranged on the upper side of the machine body and on the front side of the machine body in a side view.

An engine cover 30a that covers the upper side and the side of the engine 30 is provided on the rear side of the bonnet 39 and above the engine 30, and the work seat 41 on which the worker sits on the engine cover 30a. Is provided.

Further, the fertilizer application device 5 is loaded on the rear side of the work seat 41, specifically on the rear end side of the main frame 15. The driving force of the fertilizer application device 5 is transmitted by the fertilizer application transmission mechanism 5a arranged from the left and right sides of the left and right rear wheel transmission cases 11a toward the fertilizer application device 5.

The front side of the mission case 13 is a front transmission shaft (not shown) that transmits to the left and right front wheel transmission cases 10a and 10a, and the rear part of the mission case 13 is transmitted to the left and right rear wheel transmission cases 11a and 11a. Left and right drive shafts 42, 42 are provided. Side clutch mechanisms 43, 43 for turning on / off the transmission to the left and right drive shafts 42, 42 are arranged on the upper side in the transmission direction than the left and right drive shafts 42, 42, and the handle 35 is turned off. When the traveling vehicle body 2 is turned, the side clutch mechanism 43 located inside the turn is turned off, and the transmission to the rear wheels 11 inside the turn is stopped.

As shown in FIG. 3, left and right clutch on / off shafts 44 and 44 are provided in the vertical direction near the left and right centers on the rear side of the mission case 13, and the left and right clutch on / off shafts 44 and 44 are directed toward the outside of the machine body above the left and right clutch on / off shafts 44 and 44. Clutch on / off arms 45 and 45 are provided, respectively. Then, side clutch pedals 43a, 43a for turning on and off the left and right side clutch mechanisms 43, 43 are provided on the lower front side and one side on the left and right sides of the control seat 41.

Further, as shown in FIGS. 1 and 2, below the work device 4, a center float 62C and left and right side floats 62L and 62R that slide in contact with the field scene are provided, and the center float 62C and the left and right sides are provided. A ground leveling rotor 63 for leveling unevenness in the field scene is provided on the front side of the machine body with respect to the floats 62L and 62R. The driving force to the leveling rotor 63 is transmitted by the leveling transmission shaft 65 provided on the rear wheel transmission case 11a on one side on the left and right sides. Further, the rear wheel transmission case 11a on one side on the left and right is provided with a leveling clutch 66 for turning on / off the transmission to the leveling rotor 63.

The center float 62C is provided with a rotation potentiometer 64 for detecting the rotation angle of the center float 62C, and it is determined that the depth of the field has changed when the rotation angle of the rotation potentiometer 64 changes by a predetermined angle or more. The control device 100 expands and contracts the elevating cylinder 25 to rotate the elevating link mechanism 3 up and down, so that the vertical height of the working device 4, that is, the working position corresponds to the depth of the field.

When planting seedlings, sowing seeds, or performing topdressing or weeding after seedlings have grown using the work device 4 in the field, the vehicle body 2 travels from one side of the field to the other. It is common to drive straight ahead. However, when the wheels of the traveling vehicle body 2 face a direction deviated from the straight traveling direction due to the unevenness of the tillage board in the field or the viscosity of the topsoil, the traveling vehicle body 2 may gradually move in the deviated direction. Further, depending on the maneuvering technique of the operator, the traveling vehicle body 2 may not be aligned in the straight-ahead direction and may be moved in a direction deviated from the straight-ahead direction.

As a result, the work trajectory of planting and sowing seedlings, weeding and topdressing becomes diagonal, and the place where seedlings can be planted and sowed becomes an empty space, and the worker can manually plant the seedlings later. It becomes necessary to sow, which causes extra labor for the worker, and the space between the planting rows and the seeding rows of the seedlings becomes narrower than the gaps of the working device 4, resulting in poor ventilation and pest damage. Sometimes. Alternatively, when performing post-planting or sowing work such as weeding work or topdressing work, the seedlings may be trampled, resulting in a decrease in yield, or by maneuvering so as not to trample the seedlings. Problems that reduce work efficiency may occur.

In order to solve these problems, it is conceivable to install a so-called automatic straight-ahead system in which the traveling vehicle body 2 is automatically steered and the straight-ahead traveling posture is maintained without the hands of an operator.

First, as shown in FIGS. 1 and 2, an antenna frame 201 for mounting a GPS (GNSS) antenna 200 is provided on the traveling vehicle body 2. The antenna frame 201 includes a gate-shaped front frame 201a in front view, in which left and right bases are attached to left and right antenna stays 202 and 202 provided on the front side of the main frame 15, and an airframe from the left and right center portions of the front frame 201a. It is composed of a rear frame 201b that faces rearward and faces the left and right center portions on the rear side of the traveling vehicle body 2. It is assumed that the bonnet 39 and the control seat 41 are located behind the space portion of the gate-shaped front frame 201a.

Further, the vertical height of the antenna frame 201 is set to be the highest in the airframe. The upper end of the antenna frame 201 is located about 2.5 to 3.5 m from the ground surface in order to prevent the operator from hitting his head while standing on the floor step 33 and to improve the reception accuracy. It shall be.

As a result, the operator can easily move on the floor step 33, the work efficiency is improved, and the GPS antenna 200 can be separated upward from the ground surface, so that the reception accuracy can be improved.

The GPS antenna 200 is mounted near the connection portion between the front frame 201a and the rear frame 201b. The connection portion between the front frame 201a and the rear frame 201b is close to the front and rear of the bonnet 39 and the control seat 41, and is near the center of the traveling vehicle body 2 in the front-rear direction.

As a result of the above, since the mounting position of the GPS antenna 200 is near the center of the front-back and left-right directions of the aircraft, it is difficult for the acquired coordinates of the aircraft to deviate from the actual position of the aircraft, and the straight-ahead traveling position by the automatic straight-ahead system is used. The setting of is appropriate and the work accuracy is improved.

Further, by locating the control seat 41 behind the space portion of the front frame 201a, it is possible to prevent the antenna frame 201 from obstructing the operator's view, so that the visibility is improved and the alignment before going straight is accurate. At the same time, the state of the field in front of the machine and obstacles can be found early, so it is possible to switch to manual operation by the operator and safely and suppress the deviation of the work position.

As the GPS antenna 200, it is preferable to use a single positioning method, a DGPS (relative positioning) method, an RTK (interference positioning) method, or the like, which is suitable for the area where the work is performed.

However, if the ground height of the GPS antenna 200 fluctuates due to the influence of the tilt or vibration of the aircraft, the coordinate position different from the actual aircraft position is measured, the reception accuracy is lowered, and the aircraft travels in a direction deviating from the straight line. There is a problem that it ends up.

In order to prevent this, as shown in FIG. 6, an IMU (Inertial Measurement Unit) 203 is provided in addition to the GPS antenna 200. The IMU 203 was acquired by the GPS antenna 200 based on the difference between the height from the ground surface to the GPS antenna 200 when the traveling vehicle body 2 is in the tilted posture and the height from the ground surface to the GPS antenna 200 when the traveling vehicle body 2 is not tilted. The position coordinates are corrected by the control device 100.

The height from the ground surface to the GPS antenna 200 is determined by measuring the behavior such as the inclination of the traveling vehicle body 2 with the three-axis acceleration sensor and the angular velocity sensor built in the IMU 203.

In addition to this, the directional sensor 204 is provided so that the control device 100 can more reliably determine whether or not the traveling direction of the aircraft by the automatic straight-ahead system is correct.

The correction of the position coordinates at this time is as shown in S1 to S5 of FIG.

As a result, the course of the aircraft can be determined by the measured direction, so that the accuracy of straight running is further improved.

The position information acquired by the GPS antenna 200 is corrected by the control device 100 based on the information detected by the IMU 203 and the directional sensor 204. Then, the control device 100 compares the current position information with the previously acquired position information, and if the difference in the position information exceeds the allowable range, the left and right front wheels 10 in order to return the aircraft to the straight traveling position. , 10 are steered in the left-right direction.

In order to automate the steering of the left and right front wheels 10 and 10 or the turning of the crawler and the like, an automatic steering device 205 for rotating the steering wheel 35 with the steering actuator 206 is provided. As shown in S6 to S9 of FIG. 8, the automatic steering device 205 has a difference between the X coordinate of the current position information calculated by the control device 100 and the X coordinate of the reference position information previously acquired. Based on this, when the operating amount of the steering actuator 206 is changed, the steering wheel 35 is turned to the left and right in order to direct the aircraft to the straight running position, and when the steering actuator 206 is reached, the steering actuator 206 is stopped to automatically turn the steering wheel 35. It stops the steering.

The steering actuator 206 is composed of an electric or hydraulic motor or a cylinder.

With the above configuration, the handle 35 is automatically steered according to the difference in the X coordinates of the calculated position information, and the machine body can be automatically adjusted to the straight running position, so that the work position by the work device 4 is in the left-right direction. It is prevented from shifting, and it is less likely that there will be places in the field where work is not performed. As a result, it is not necessary to manually perform the work later in the place where the work was not performed, and the labor of the worker is reduced.

In addition, since it is possible to prevent the work positions of the work line of the previous process and the work line of the current work line from overlapping, it is possible to prevent extra consumption of work materials such as seedlings, seeds and fertilizers, and to reduce work costs. At the same time, the occurrence of poor growth due to excessive supply of work materials is prevented.

The tractor equipped with the tiller, the seedling transplanter, and the sowing machine travel to the field edge of the work line, turn about 180 degrees, and move to the next work line. If the automatic straight-ahead system is operating during turning, it may be determined that the aircraft is out of the position where it should be running straight, and the steering actuator 206 may be operated to disturb the turning trajectory. Therefore, the automatic straight-ahead system needs to be configured to be turned off when turning the aircraft. It is conceivable that the automatic straight-ahead system will be turned off when the steering wheel 35 is turned, but the traveling direction of the aircraft may be significantly deviated depending on the conditions of the field, or the operator may turn the steering wheel 35 to avoid obstacles. Since the automatic straight-ahead system is turned off when the operation is made larger than the operation, the operator has to turn on the automatic steering system again while going straight, which increases the labor of the operator and the automatic straight-ahead system. There is a problem that the work accuracy is lowered because the aircraft runs while the work position is shifted without noticing that it is turned off.

In addition, it is conceivable to turn on the automatic straight-ahead system by returning the handle 35 from turning to straight-ahead. It is necessary to perform steering operation. If the automatic steering system is turned on during this operation, the steering actuator 206 will operate when the control device 100 determines that the aircraft has deviated from the straight traveling position, and the position of the aircraft will be adjusted to the position where the aircraft should originally travel straight. There is a problem that it cannot be done.

An automatic straight-ahead system capable of preventing the occurrence of this problem, allowing the aircraft to travel straight in an appropriate direction, and operating in an appropriate section will be described with reference to FIGS. 6 and 8 to 11.

The position coordinates in the forward / backward traveling direction of the traveling vehicle body 2 are defined as Y coordinates, and the position coordinates in the direction orthogonal to the traveling vehicle body 2 in the forward / backward traveling direction, that is, in the left-right direction are defined as X coordinates.

First, the automatic straight-ahead setting member 207 that causes the traveling vehicle body 2 to acquire the coordinates of one side of the field that is the start point of the automatic straight-ahead and the other side of the field that is the end point of the automatic straight-ahead, and turns on / off the automatic straight-ahead system. Is provided. The automatic straight-ahead setting member 207 is equipped with at least one member that can be operated in at least two directions such as a vertical direction, a horizontal direction, a pushed state and a return state, or is equipped with two or more operating members. ..

In the present application, as the automatic straight-ahead setting member 207, a finger-up lever that can be operated in the vertical direction is attached as shown in FIG. 4, but a toggle switch, a push switch, a joystick, or the like may be used.

As a result, the number of parts can be reduced, and the acquisition operation of the reference position (first reference position A, second reference position B) and the on / off operation of the automatic steering device 205 are automatically performed with one hand on the same side. Since the straight-ahead setting member 207 may be operated, the operability is improved.

As shown in FIG. 4, when the automatic straight-ahead setting member 207 is operated in the first direction W1 toward the upper part of the machine body in the present application (see S10 and S11, FIG. 9), the GPS antenna 200 is used at the operated position. The position information is acquired, and the position coordinates calculated by the control device 100 using the detection results of the IMU 203 and the azimuth sensor 204 are recorded. The operation of the automatic straight-ahead setting member 207 in the first direction W1 corresponds to the operation of the reference position acquisition member.

When the automatic straight-ahead setting member 207 is operated and there is no recording of other position coordinates, the calculated position coordinates are recorded as the first reference point A (S12 and S14), and the first reference point A is recorded. If so, the calculated position coordinates are recorded as the second reference point B. When the automatic straight-ahead setting member 207 is operated while the first reference point A and the second reference point B are recorded, the position coordinates are not recorded.

If the automatic straight movement cannot be performed accurately during the work in the field, it is necessary to reacquire the first reference point A and the second reference point B. Therefore, as shown in FIG. 10, at this time. Operates the automatic straight-ahead setting member 207 in the first direction W1 for a predetermined time (eg, 2 to 3 seconds) (S22 and S23), and the recorded first reference points A and second reference points are recorded. It is preferable to set B to be erased (S24 to S27). Alternatively, a record erasing button (not shown) may be provided in which the first reference point A and the second reference point B are deleted when operated.

As for the first reference point A and the second reference point B, which are the reference positions for the straight running of the automatic straight running system, the deviation of the X coordinate is smaller as the distance is shorter, but if the distance between the two points is short, the automatic straight running is used. It is possible to drive straight ahead without it. Further, when the distance between the two points becomes short, it is conceivable that the operator unintentionally touches the automatic straight-ahead setting member 207 and acquires the second reference point B.

In order to prevent the occurrence of this problem, when the automatic straight-ahead setting member 207 is operated to acquire the second reference point B, the distance from the position where the first reference point A is acquired is less than a predetermined distance, for example, 8 to 12 m. If it is less than, the control device 100 deletes the second reference point B and prevents recording. After that, if the automatic straight-ahead setting member 207 is operated again and the distance from the position where the first reference point A is acquired is equal to or greater than a predetermined distance (S13 and S15), the control device 100 records the second reference point (S16). ), The reference line R shall be created (S17).

As shown in FIG. 11, in the state where the first reference point A is acquired (S28 and S29), the handle 35 is operated by a predetermined amount or more within a predetermined time without acquiring the second reference point B (S30 and S29). S31), when the traveling vehicle body 2 is turned, the control device 100 deletes the recorded first reference point A (S32). After that, when the automatic straight line setting member 207 is operated in the first direction W1, the control device 100 records the position coordinates of the place acquired by the GPS antenna 200 as the first reference point A, and records the position coordinates as the first reference point A. It may be configured to prevent the line connecting the Y coordinate of the point A and the Y coordinate of the second reference point B from becoming straight.

As a result, the first position is a predetermined position at one end and the other end of the field, for example, a position where the traveling vehicle body 2 starts turning after the straight running and a position where the working device 4 is lowered to start the straight running after the turning is completed. The reference point A and the second reference point B can be set, the automatic straight-ahead system is operated at the position where the work device 4 is lowered and the work device 4 travels straight, and the work position does not shift in the left-right direction with respect to the traveling direction. Accurate work is possible.

In addition, since it is possible to prevent the second reference point B from being different from the actual position to be set due to an erroneous operation by the operator, there is no need to reacquire the first reference point A and the second reference point B in the next work section. , The number of work lines that use automatic straight-ahead can be increased, and the work accuracy in the field can be further improved.

In the work line where the work is performed first after entering the field, the automatic straight-ahead setting member 207 is operated in the first direction W1 at a predetermined position to acquire the above-mentioned first reference point A and second reference point B. Since the work to be performed is indispensable, the operator operates the handle 35 to drive the aircraft straight ahead without using automatic straight travel.

As described above, when the first reference point A and the second reference point B are acquired by the operation of the automatic straight-ahead setting member 207, the reference connecting the Y coordinates of the first reference point A and the second reference point B. The line R becomes a line that serves as a guideline for automatic straight-ahead, and it is determined whether or not the X-coordinate of the position coordinate of the running aircraft matches the X-coordinate of the line that serves as a guideline for automatic straight-ahead. For example, by automatically steering the steering wheel 35 in the matching direction by the automatic steering device 205, automatic straight running can be realized.

In the above automatic straight running, the automatic straight setting member 207 is set in the second direction W2 in the state where the first reference point A and the second reference point B are recorded and the reference line R is created (S18). Then, it is started by operating toward the lower side of the aircraft (S19 and S21). When the automatic straight-ahead setting member 207 is operated in the second direction W2, the control device 100 compares the Y coordinate of the position coordinate acquired by the GPS antenna 200 with the Y coordinate of the reference line R, and operates the steering actuator 206. The handle 35 is rotated in the left-right direction, and control for moving the traveling vehicle body 2 to a position where the traveling vehicle body 2 should travel straight is started. The operation of the automatic straight-ahead setting member 207 in the second direction W2 corresponds to the operation of the on / off member.

This automatic steering control ends when the steering wheel 35 is operated to an angle at which the traveling vehicle body 2 is turned within a predetermined time, or when the automatic straight-ahead setting member 207 is operated in the second direction W2 (S20). .. The steering angle of the steering wheel 35 shall be detected by the steering wheel potentiometer 35a.

The automatic straight-ahead control may be terminated when the traveling vehicle body 2 reaches a place that coincides with the Y coordinate of the first reference point A or the second reference point B.

As described above, the automatic straight-ahead control is terminated by turning the steering wheel 35 or reaching the vicinity of the start point of the turning run at the field edge. Since the position where the traveling vehicle body 2 turns is close to the field edge, if the operator is performing work other than maneuvering by leaving it to the automatic straight-ahead control, if the turning operation is delayed, the seedlings will be placed in an unplanned position. Along with the planting, the traveling vehicle body 2 moves to the edge of the field, and it is necessary to move backward to the position where the turning is performed, which causes a problem that the work efficiency is lowered.

Note that FIG. 12 is a schematic diagram showing the first reference position A, the second reference position B, the reference line R, the target position, and the current position of the aircraft.

In order to prevent this problem, as shown in FIGS. 6 and 13, a work detection sensor 209 for detecting the on / off of the ground leveling rotor 63 due to the on / off (operation) and off (stop) of the ground leveling clutch 66 is provided to detect the work. When the sensor 209 detects the entry (operation) of the leveling rotor 63 (S33), the control device 100 acquires the target position coordinates (end reference position) which are the position coordinates (X coordinate and Y coordinate) of the traveling vehicle body 2. (S34 and S35). The target position coordinates can be simultaneously held in the control device 100 or the memory area attached to the control device 100 at at least two locations.

The acquisition of the target position coordinates (end reference position) by the work detection sensor 209 is performed by raising or lowering the work device 4, turning on or off the transmission to the work device 4, and handling the handle 35, instead of turning the ground leveling rotor 63 on and off. It may be configured to perform the turning start steering or the turning end steering on condition.

Then, in the work section following the work section in which the position coordinates are acquired, when the automatic steering device 205 is operated to automatically drive the traveling vehicle body 2 in a straight line, the control device 100 receives the current position coordinates acquired by the GPS antenna 200. The distance from the Y coordinate to the Y coordinate of the target position coordinate acquired in the immediately preceding work line (most recent work line) is sequentially calculated (S36). At this time, the control device 100 may be configured to correct the X coordinate of the target position coordinate to the X coordinate of the current position coordinate.

Then, when the traveling vehicle body 2 reaches the notification position where the distance from the current position coordinates to the target position coordinates is a predetermined distance, for example, 8 to 12 m (S37), the traveling vehicle body 2 is approaching the field edge, and the automatic operation is performed. A notification device 208 that displays numerical values or characters on a buzzer, a lamp, or a screen in order to notify the operator that it is necessary to operate the straight-ahead setting member 207 in the second direction W2 to end the automatic straight-ahead control. It is configured to operate (S38).

The notification device 208 displays numerical values and characters by providing a display panel (not shown) on the traveling vehicle body 2 or by transmitting information to an information terminal (smartphone, tablet, etc.) brought by the operator. The configuration to make it is conceivable.

In addition, since the distance between the traveling vehicle body 2 and the target position cannot be calculated in the work strip for which the target position coordinates have not been acquired, the operator visually confirms the field edge and determines that automatic straight-ahead control is unnecessary. It is necessary to operate the automatic straight-ahead setting member 207.

Regarding the distance from the current position coordinates to the target position coordinates, the rear wheel rotation sensors 210 and 210 for detecting the rotation of the left and right drive shafts 42 and 42 to the left and right rear wheels 11 and 11 are provided, and the ground leveling rotor 63 is provided. The control device 100 calculates the moving distance from the turned-in position based on the number of rotations detected by the rear wheel rotation sensors 210 and 210, and reaches the Y-coordinate position of the moved distance and the position where the ground leveling rotor 63 is turned on. The distance may be calculated and the notification device 208 may be operated if it is within a predetermined distance.

However, even if the notification device 208 is activated, the traveling vehicle body 2 cannot be turned at an appropriate position unless the operator notices and ends the automatic straight-ahead control. In order to cope with this, the traveling vehicle body 2 moves forward for a predetermined distance (for example, 2 to 5 m) after the notification device 208 is activated, without the automatic straight-ahead setting member 207 being operated in the second direction W2. When traveling (S39 to S41), the control device 100 rotates the trunnion shaft 14a of the continuously variable transmission 14 to decelerate the traveling vehicle body 2 (S42).

Alternatively, instead of the distance, the traveling vehicle body 2 does not operate the automatic straight-ahead setting member 207 in the second direction W2 for a predetermined time (for example, 2 to 5 seconds) after the notification device 208 is activated. When traveling forward, the control device 100 reduces the output of the continuously variable transmission 14 and decelerates the traveling vehicle body 2.

To decelerate the traveling vehicle body 2, the HST servomotor 211 that rotates the trunnion shaft 14a of the continuously variable transmission 14 via a trunnion arm (not shown) is operated, and the trunnion shaft 14a is rotated to the deceleration side. It is done by letting.

As a result, when the traveling vehicle body 2 approaches the field edge, the traveling speed of the traveling vehicle body 2 decreases, so that the operator can be made to recognize that the turning position of the field edge is approaching, and the turning traveling can be performed on an appropriate trajectory. Therefore, it is prevented that the working device 4 performs the ground work overlappingly on the four sides of the outer periphery of the field, that is, the so-called headland, and consumes extra work materials (seedlings, fertilizers, chemicals, etc.).

Further, since the position where the ground leveling rotor 63 is turned on after turning and the ground leveling work is started can be adjusted to the position where the ground leveling work is completed before turning, there are some places where the ground leveling work is not performed by the ground leveling rotor 63, and the ground leveling work is not performed. Occurrence of places where ground work is not performed by the work device 4 is prevented. As a result, problems such as the planting depth of seedlings being disturbed, the permeation of fertilizer being different, and the running being disturbed can be prevented in places where the ground leveling work was not performed, and the position where the ground work was not performed. As for, the worker does not have to perform the work manually, and the labor of the worker is reduced.

In the above automatic deceleration, the traveling speed is gradually reduced with the passage of time, and if the control configuration is such that the speed is gradually decelerated, the ground leveling accuracy of the work device 4 and the leveling rotor 63 are lowered, and the operator Is prevented from being shaken.

Alternatively, if the control configuration is such that abrupt deceleration is performed once or a plurality of times at predetermined time intervals after the start of automatic deceleration, the operator can easily notice the approach of the field edge due to the shaking of the traveling vehicle body 2.

Further, when the automatic straight-ahead setting member 207 is operated to cancel the automatic straight-ahead control within a predetermined time (second predetermined time) in which the automatic deceleration control is performed (S43 and S44), the control device 100 causes the control device 100 to cancel the automatic straight-ahead control. It may be configured to maintain the running speed at the time point. As a result, since the work running does not stop, it is possible to quickly shift to the turning running at the field edge, and the deterioration of the work efficiency is prevented.

Alternatively, the control device 100 operates the HST servomotor 211 of the continuously variable transmission 14 to shift to the preset traveling speed or the traveling speed at the time when the automatic deceleration is started, and the trunnion shaft 14a May be configured to rotate to the speed increasing side.

Since the traveling speed is automatically increased, it is not necessary for the operator to operate the speed change operation lever 36 to increase the traveling speed, so that the operability is improved.

In addition to the operation of the notification device 208, it is expected that the traveling vehicle body 2 recognizes the turning position near the field edge, specifically, the field edge by the automatic deceleration control of the traveling vehicle body 2, but the operator It is assumed that the worker may not notice the automatic deceleration of the running speed because he / she is absorbed in another work or the worker faints.

Therefore, the automatic deceleration control of the traveling vehicle body 2 is performed until the continuously variable transmission 14 is in a neutral state in which the traveling speeds of both forward and reverse are not increased or decreased. At this time, the engine 30 is not stopped. As a result, the traveling vehicle body 2 can be stopped on the spot (S45), so that it is prevented from moving forward until the aircraft comes into contact with the field edge, so-called ridges, and the aircraft is damaged or the aircraft is moved backward to return to work. The distance to make it is suppressed.

When the traveling vehicle body 2 automatically stops traveling due to the approach to the field edge, the speed change operation lever 36 for operating the traveling vehicle body 2 increases / decreases and moves forward and backward is returned to the neutral position, and the control device 100 changes continuously. The device 14 is set to accept the operation of increasing / decreasing the traveling speed. Then, when the shift operation lever 36 is operated to the forward side, the traveling vehicle body 2 is restarted. As a matter of course, when the auxiliary transmission operation lever 37 is operated to the neutral position and the driving force is not transmitted to the traveling system, the traveling is continued until the auxiliary transmission operating lever 37 is operated to the position where the traveling transmission is performed. Not started.

The reference line R connecting the first reference point A and the second reference point B and the first reference point A and the second reference point B, which is the reference for the automatic straight-ahead control, goes straight from one end to the other end of the field. It is necessary for work running and straight work running from the other end to one end of the field.

However, although the work running on the four sides of the field, the so-called headland, is a straight-ahead work run, there is one work side that has a different traveling direction from the above-mentioned straight-ahead work run, and the reference line R is used for that work side. However, automatic straight-ahead control cannot be performed.

Further, when the aircraft is moved to the loading platform of a transport truck or stored in a barn outside the field, the automatic straight-ahead setting member 207 is mistakenly operated in the second direction W2 to be an automatic steering device. When the 205 is in an operable state, the X coordinate of the reference line (R) and the X coordinate of the aircraft do not match when the aircraft is moved, and it is determined that the 205 is deviated from the straight running position, and the automatic steering device 205 is used. It may happen that the steering wheel 35 is automatically steered. As a result, the course of the aircraft is deviated from the originally intended course, and extra labor is required for loading and storing the aircraft.

To prevent this, it is necessary to erase the first reference point A, the second reference point B, and the reference line R before the aircraft leaves the field. As shown in FIGS. 6 and 14, when the traveling vehicle body 2 travels on three sides of the four sides of the field, including at least one side in the traveling direction orthogonal to the traveling direction in which the traveling vehicle travels in a straight line (S46 to S49), the pillow Upon determining that the ground work has been performed, the control device 100 causes the first reference point A, the second reference point B, and the reference line R to be deleted (S50 and S51).

The traveling direction of the traveling vehicle body 2 on the headland is determined by the continuous change of the X-axis coordinate or the Y-axis coordinate among the position coordinates of the traveling vehicle body 2 acquired by the GPS antenna 200.

As a result, the first reference point A, the second reference point B, and the reference line R can be deleted while the aircraft is traveling in the field, so that the automatic straight-ahead setting member 207 can be used after going out of the field. Even if it is operated, it does not go straight automatically, it is prevented from traveling in a direction deviating from the planned traveling direction, a decrease in work efficiency is prevented, and work safety is improved.

In addition, when the aircraft is moved to another field, the first reference point A, the second reference point B, and the reference line R are not recorded, so that the automatic operation is based on the reference line R that is not suitable for the field being worked on. Since it is possible to prevent straight-ahead control, the accuracy of automatic straight-ahead is improved.

When moving out of the field, the auxiliary shift operation lever 37 is operated to the traveling position in order to move the truck to the truck for transfer or to the barn in a short time. When the auxiliary shift position detection switch 37a for detecting the operation of the auxiliary shift operation lever 37 to the traveling position is provided and the auxiliary shift position detection switch 37a detects that the auxiliary shift operation lever 37 is operated to the traveling position, the first step is made. The reference point A, the second reference point B, and the reference line R may be deleted.

By deleting the first reference point A, the second reference point B, and the reference line R based on the operation of the auxiliary shift operation lever 37 to the traveling position that is not used in the field, the first reference point is traveled on the headland. When A, the second reference point B, and the reference line R are not deleted, they can be reliably deleted, so that automatic straight-ahead control is not performed when the traveling vehicle body 2 is moved or when working in another field. The deterioration of work accuracy is prevented.

Further, since it is possible to prevent the first reference point A, the second reference point B, and the reference line R from being accidentally deleted in the field due to the erroneous operation of the auxiliary shift operation lever 37, the first reference point A and the second reference point A can be prevented. The work line for reacquiring the point B prevents the automatic straight movement from becoming unusable, and the work accuracy is improved.

Alternatively, when the traveling vehicle body 2 is tilted forward by a predetermined angle or more (for example, 10 to 15 degrees) by using the IMU 203 or the inclination sensor 212 that detects the inclination of the traveling vehicle body 2 in the front-rear and left-right directions, the control device is used. Reference numeral 100 may be configured to delete the first reference point A, the second reference point B, and the reference line R.

When leaving the field, the traveling vehicle body 2 passing through the doorway of the field is in a forward-upward tilting posture at an angle that cannot be abbreviated during work. Therefore, when this tilting angle is detected, it is time to leave the field. I can judge.

As a result, when the first reference point A, the second reference point B, and the reference line R are not deleted when traveling on the headland, they can be reliably deleted, so that the traveling vehicle body 2 can be moved or work in another field. Occasionally, automatic straight-ahead control is not performed, and deterioration of work accuracy is prevented.

Depending on the field and the content of the work, it is possible to move the traveling vehicle body 2 backward and exit from the entrance / exit. A control configuration may be used in which B and the reference line R are deleted.

Even when the traveling vehicle body 2 is automatically driven straight by the automatic steering device 205, when the work material consumed by the work device 4 or the like is replenished, or when a problem occurs in the machine body or the field, etc. , The worker needs to stop running. In this running stop operation, the speed change operation lever 36 is operated to the neutral position to neutralize the continuously variable transmission device 14, the brake pedal is stepped on to apply the brake, and the side clutch pedal 43a is stepped on to disengage the side clutch 43. The method of making it into a state is conceivable.

The control device 100 does not stop the automatic steering device 205 even when the traveling vehicle body 2 is stopped by any of the above methods.

As a result, when the running stop is released by moving the shift operation lever 36 forward, canceling the operation of the brake pedal or the side clutch pedal 43a, etc., it becomes possible to immediately return to the automatic straight running, and the work efficiency becomes high. Is prevented from decreasing.

However, if the steering wheel 35 is manually steered while stopped, or if the automatic steering device 205 is activated and the steering wheel 35 is automatically steered, the traveling direction at the time of restarting the automatic straight running will deviate from the traveling direction at the time of stopping. , There is a risk that the traveling direction of the traveling vehicle body 2 will not be linear.

In particular, when the traveling vehicle body 2 is stopped, the position coordinates acquired by the GPS antenna 200 are easily affected by the rotation of the earth, the revolution of the GPS satellite, etc., and are different from the actual positions where the traveling vehicle body 2 exists. Coordinates may be acquired, and it is easy to be mistaken for being at a position away from the reference line R.

In order to prevent this, a lever potentiometer 36a that detects the operation position of the shift operation lever 36 and a stepping detection switch 213 that detects the stepping operation of the brake pedal or the clutch pedal are provided, and the operation of stopping the running during automatic straight running is performed. When detected, the control device 100 does not reflect the steering operation of the handle 35 or makes the handle 35 immobile.

The configuration that does not reflect the steering operation of the steering wheel 35 means that the steering actuator 206 is not operated even if the X coordinate of the position coordinate of the traveling vehicle body 2 when the vehicle is stopped deviates from the X coordinate of the reference line R by a predetermined value or more. ..

Further, the configuration in which the steering wheel 35 is immobile means that the operating torque of the steering actuator 206 is increased to bring the steering wheel into a locked state.

With the above configuration, it is possible to prevent the traveling direction from shifting after resuming the traveling, so that the working traveling is performed in a straight line and the working accuracy is improved.

The steering wheel 35 is automatically steered by the steering actuator 206 during automatic straight running, but the state of the field on the course is not suitable for automatic straight running (rough, deep field depth, etc.), and there are obstacles. In such situations, it is necessary to take evasive action by manual operation.

The steering operation of the steering wheel 35 by the steering actuator 206 is performed by the following configuration. An input gear 352 is provided at the lower part of the steering wheel shaft 351 that rotates in conjunction with the steering operation of the steering wheel 35, and an output gear 353 is provided at the steering actuator 206.

The input gear 352 and the output gear 353 are housed in a steering gear case 354 arranged below the steering wheel 35 and the steering actuator 206. Then, a relay gear 355 for transmitting the driving force by changing the transmission ratio is provided between the input gear 352 and the output gear 353.

The gear ratios of the input gear 352, the output gear 353, and the relay gear 355 are the gear ratios in which the torque due to the manual operation becomes stronger even when the steering actuator 206 is operating in order to prevent the manual operation of the handle 35 from being hindered. do.

As a result, it is possible to prevent the force required for the manual operation of the steering wheel 35 from increasing even during automatic straight movement, so that the operability is improved and the fields and obstacles in a state that may affect the running are surely avoided. Because it can be done, the safety of work is ensured.

From here, a more specific configuration and operation of the seedling transplanting machine of the present embodiment will be described.

The work device 4, the center float 62C, and the leveling rotor 63 are devices attached to the traveling vehicle body 2. The handle 35 is a member that steers the traveling vehicle body 2. The GPS antenna 200 is a device that acquires the position information of the traveling vehicle body 2. The automatic straight-ahead setting member 207 is a member that receives a user instruction for acquiring reference position information used when the traveling vehicle body 2 travels straight. The automatic steering device 205 is a device that operates the steering wheel 35 so as to drive the traveling vehicle body 2 straight. The control device 100 is a device that executes automatic straight-ahead control for causing the automatic steering device 205 to operate the steering wheel 35 based on the reference position information. The control device 100 calculates a straight-ahead reference line R and a single or a plurality of straight-ahead target lines T parallel to the straight-ahead reference line R based on the reference position information, and mounts the control device 100 on the traveling vehicle body 2 by using wireless communication. The straight reference line R and the straight target line T can be displayed on the tablet terminal 1000.

The position information of the traveling vehicle body 2 acquired as the reference position information may be calculated at a timing according to a user instruction using the automatic straight-ahead setting member 207 so that more accurate reference position information can be obtained. Regardless of the instruction, it may be selectively specified according to the user instruction from the position information calculated periodically.

More specifically, it is as follows.

That is, the position information is periodically calculated by receiving the signal transmitted from the GPS satellite in order to display the traveling locus L, etc., regardless of the user's instruction using the automatic straight-ahead setting member 207. There is. Such periodic position information calculation may be performed at fairly small time intervals using all of the signals transmitted from the GPS satellites, or a part of the signals transmitted from the GPS satellites. It may be used and performed at slightly larger time intervals. In the former case where the position information is calculated at a considerably small time interval, the position information calculated at the timing closest to the user instruction using the automatic straight-ahead setting member 207 is preferably adopted as the reference position information. In the latter case where the position information is calculated at a slightly large time interval, the position information calculated at the timing closest to the user instruction using the automatic straight-ahead setting member 207 may be similarly adopted as the reference position information. However, in order to obtain more accurate reference position information, the position information specially calculated at the timing according to the user instruction may be suitably adopted as the reference position information.

Seedlings such as rice planters that are equipped with a GNSS antenna 200, an IMU203 as an inertial measuring device having a three-axis acceleration sensor and an angular speed sensor such as a gyroscope, and a steering actuator 206 as a steering motor, and automatically go straight. In the transplanter, instruct the automatic setting switch that can set and reset the automatic straight-ahead, the first reference point A where the automatic straight-ahead reference line R starts, and the second reference point B where the straight-ahead reference line R ends for each field. An automatic straight-ahead setting member 207 that also serves as an operation switch is provided, and the straight-ahead reference line R and the straight-ahead target line T parallel to the straight-ahead reference line R are displayed on a monitor such as a tablet terminal 1000. Information on the R and the straight target line T is transmitted from the wireless transmission / reception unit 100y of the control device 100 as a vehicle controller to the tablet terminal 1000 by wireless communication such as Bluetooth (registered trademark).

Of course, such an operation switch that indicates the first reference point A and the second reference point B may be a switch provided separately from the automatic setting switch for automatic straight movement.

In a commercially available automatic straight-ahead guidance device, a signal is detected by wire communication between a main body monitor fixed to a traveling vehicle body 2 and a GPS antenna 200 on which point AB operation is performed.

In the present embodiment, the tablet terminal 1000 as a commercially available tablet can be used via wireless communication, and automatic straight-ahead guidance can be easily provided.

The seedling transplanting machine of the present embodiment is established as a product having a function of displaying information on driving operations, guidance guides, etc., even without an automatic straight-ahead guidance function.

For example, by displaying the straight-ahead target line T on the tablet terminal 1000 together with a virtual line showing the left-right width of the traveling vehicle body 2 in which the work device information is also taken into consideration, it is intuitive whether or not the straight-ahead of the machine body by the automatic steering device 205 is correct. Since it is easy to make a judgment, even if the traveling position is far from the position where the vehicle should automatically travel straight, it can be corrected at an early stage, and accurate straight traveling work becomes possible.

By using the detachable tablet terminal 1000 as an information display device, a dedicated display is not required, so that the number of parts can be reduced and a harness for connection is not required, which improves maintainability. Further, if the display of the straight target line T is unnecessary, the tablet terminal 1000 can also be omitted.

Since the automatic straight-ahead setting member 207 is mounted as a user-operated lever, the reference position for straight-ahead travel is automatically acquired when the work device 4 or the like is turned on or off due to an erroneous operation, as in the above-mentioned prior art. That is prevented.

More specifically, it is as follows.

By displaying the reference line R and the traveling locus L on the display of the tablet terminal 1000, it is possible to visually determine whether or not the automatic steering device 205 is operating and whether or not an abnormality has occurred in the automatic straight traveling. It is possible to prevent the work locus from being disturbed and the automatic straight running from deviating from the locus that should be originally traveled by performing the work running without operating the automatic steering device 205.

The tablet terminal 1000 is detachably attached to the vehicle body and is wirelessly connected to the wireless transmission / reception unit 100y of the control device 100 that controls the automatic steering device 205, so that the number of parts of the device does not increase and the maintainability deteriorates. There is no.

Further, since the display of the tablet terminal 1000 does not display only the information related to the straight running such as the reference line R and the running locus L of the automatic straight running, it is necessary to prepare another display for displaying other information. do not have. As a result, since the worker does not need to see a plurality of displays, the labor of the worker does not increase, and there is no problem that the visibility around the machine body is deteriorated because the displays are not arranged at a plurality of places.

The reference position information is the first reference position information corresponding to the first reference point A where the straight reference line R starts, and the second reference position information corresponding to the second reference point B where the straight reference line R ends. When the first reference position information is acquired, the traveling locus L of the traveling vehicle body 2 is displayed on the tablet terminal 1000. When the second reference position information is acquired, the straight target line T is displayed on the tablet terminal 1000.

When the tablet terminal 1000 receives the setting start information of the straight reference line R (information for setting the first reference point A) by wireless communication from the wireless transmission / reception unit 100y of the control device 100, the tablet terminal 1000 displays the travel locus L. To start. The information of the traveling locus L is displayed based on the GNSS position information periodically wirelessly transmitted from the wireless transmission / reception unit 100y of the control device 100.

Even if the straight reference line R itself is not displayed yet, the start of setting the straight reference line R can be confirmed on the monitor because the travel locus L is displayed, which gives a sense of security.

When the tablet terminal 1000 receives the setting end information of the straight reference line R (information for setting the second reference point B) by wireless communication from the wireless transmission / reception unit 100y of the control device 100, the tablet terminal 1000 goes straight from the next step onward. The target line T is displayed.

The straight target line T displayed on the screen for the next step and thereafter can be used as a guide even when the marker line or the like is difficult to see due to deep water during turning.

15 (a) to explanatory views (Nos. 1 to 5) of the time-dependent display of the straight reference line R, the straight target line T, and the traveling locus L in the tablet terminal 1000 of the seedling transplanting machine according to the embodiment of the present invention. As shown in (e), the straight reference line R, the straight target line T, and the traveling locus L are displayed.

In FIG. 15A, a traveling map of the field where the first reference position information corresponding to the first reference point A is received is shown. In FIG. 15B, a traveling map of the field where the traveling locus L has begun to be displayed is shown. In FIG. 15C, a traveling map of a field where the second reference position information corresponding to the second reference point B is received and the straight reference line R is displayed is shown. In FIG. 15D, a traveling map of the field in which the straight target line T is generated and displayed according to the number of model lines is shown. In FIG. 15 (e), a traveling map of a field in which the traveling locus L is continuously displayed according to the traveling progress is shown.

The automatic steering device 205 by displaying the traveling locus L on the tablet terminal 1000 based on the acquisition of the first reference position A and displaying the straight reference line R on the tablet terminal 1000 based on the acquisition of the second reference position B. It becomes easier for the operator to confirm that the automatic steering device 205 is operating, and it is possible to prevent the automatic steering device 205 from performing the work while it is not operating.
By displaying the straight target line T from the next step onward, it is possible to visually determine the position where it is desirable to move the aircraft during turning at the field edge, regardless of whether or not the traveling locus L during turning is displayed. Since it is easy to grasp based on intuition, there is no need to correct the position of the aircraft after turning.

The leveling clutch 66 is a clutch that turns on and off the power transmitted to the leveling rotor 63. The work detection sensor 209 is a sensor that detects the on / off state of the power transmitted to the leveling rotor 63. The traveling locus L is displayed on the tablet terminal 1000 when the on state of the power transmitted to the leveling rotor 63 is detected by the work detection sensor 209.

In FIG. 16, which is an explanatory diagram of the automatic straight running of the seedling transplanting machine according to the embodiment of the present invention, a field provided with a field entrance / exit 1601 which is both an approach road entrance and an exit road exit is shown, and the working width is shown. In order to make it easy to understand, the positions substantially corresponding to the starting points of the working device 4 at both end points of each work strip are indicated by white rectangles. The traveling locus L composed of a plurality of line segments adjacent to each other in the X direction substantially parallel to the straight-ahead reference line R is a locus obtained by automatic straight-ahead traveling, and is shown by a long-dotted chain line. The end point close to the field end of the straight target line T is not determined from the first reference position information and the second reference position information. However, since the turning at the end of the field is performed not by automatic straight running but by manual running, the user is urged to switch from automatic straight running to manual running by using a buzzer or the like. More specifically, the on / off position of the leveling rotor 63 is recorded in the memory area, and the buzzer is, for example, the position in the immediately preceding work line where the leveling rotor 63 cut before turning is reinserted after turning. It is sounded with a time margin at the position 1604 having the Y coordinate determined based on the Y coordinate possessed by the 1603. In the corridor portion outside the automatic straight traveling area 1602 where automatic straight traveling is possible, headland traveling may be performed.

In the embodiment of the modification, the traveling locus L may be displayed on the tablet terminal 1000 when the on state of the power transmitted to the work device 4 is detected by the work detection sensor 209.

In FIG. 17, which is an explanatory diagram of the automatic straight running of the seedling transplanting machine according to another embodiment (No. 1) of the present invention, the length in the Y direction is the Y coordinate of the planting portion descending point 1701 and the planting portion ascending. The planting portion elevating measurement area 1703 measured based on the elevating and lowering of the planting portion of the working device 4 to be turned on and off by the planting clutch, which is determined based on the Y coordinate of the point 1702, is shown. Since the GNSS antenna 200 is mounted on the front end of the traveling vehicle body 2, the Y coordinate of the planting portion descending point 1701 is almost equal to the minimum Y coordinate of the automatic straight traveling region 1704, but the Y coordinate of the planting portion rising point 1702 is It is slightly larger than the maximum Y coordinate of the automatic straight running area 1704.

The travel locus when turning by manual travel instead of automatic straight travel is not displayed, and the travel locus L when traveling down the planted portion of the work device 4 is periodically measured by wireless communication of the control device 100. The GNSS position data transmitted from the wireless transmission / reception unit 100y is displayed on the monitor screen of the tablet terminal 1000.

Then, the history of the actual running locus by the automatic straight running can be left.

Regarding the display of the traveling locus L, the locus is left only when it is in the planted state.

Then, the history of the planting travel locus can be left.

Regarding the display of the traveling locus L, the locus is left only when the planting state is in the planting state, and the planting state is the time when the planting clutch is engaged.

Then, the history of the actual planting travel locus can be left.

Regarding the display of the traveling locus L, the locus is left only when it is in the planting state, and the planting state is when the leveling rotor 63 is turned on.

Then, the history of the traveling locus corresponding to the actual planting traveling locus can be left.

By displaying the travel locus L during straight travel using the work device 4, it is possible to determine whether or not the intended straight travel is being performed. Therefore, if it is inappropriate, the operator corrects it at an early stage. It is possible to optimize the work.

Unworked area between adjacent worked strips and current working strips (eg, areas where soil is not cultivated, or areas where the spacing between seedlings (left-right spacing) is wider than the set spacing of the work machine, etc. ) Occurs, and it can be determined at an early stage whether the work areas overlap, so that the work can be optimized.

When the control device 100 calculates the straight target line T, the control device 100 takes into account the work device information regarding the work device 4.

Based on the vehicle model model information stored in the control device 100 and the vehicle model model information in the memory of the tablet terminal 1000, the row width and the number of rows (8 rows planted with a 30 cm row width or 8 rows planted with a 33 cm row width). Etc.), calculate the work width, and display the straight target line T for the next and subsequent steps. Since the vehicle data of the tablet terminal 1000 is confirmed by receiving the wireless information, an accurate history of the planting travel locus can be recorded.

Regarding the running target line display, a straight line parallel to the straight line connecting the first reference point A and the second reference point B is displayed as all or part of the straight line target line T from the next step onward, so that it is displayed at a relative position. The target position can be displayed. For example, if it turns out that it is difficult to carry out automatic straight running, the obtained data is accumulated for use as a reflection material for the next work or for soil improvement. May be good.

Since the straight target line T is displayed as a thin line and the traveling locus L is displayed as filling the work width, the guidance display is easy to understand.

By displaying the straight-ahead target line T on the tablet terminal 1000 with reference to the left-right width of the work device 4, the work positions of the work device 4 do not overlap and there is no space between the work positions. Since the traveling locus L of the tablet can be shown, it becomes easy to determine whether or not the traveling direction by the automatic straight running is appropriate.

Since it is easy to grasp the position where it is desirable to move the aircraft when turning at the field edge based on visual intuition, it is not necessary to correct the position of the aircraft after turning.

The tablet terminal 1000 displays a traveling map program for displaying the straight reference line R and the straight target line T, a field depth map program for displaying the depth of the field, and the amount of material sprayed on the field. A management application that can select a predetermined program from the material spray amount map program for the purpose is installed, and a map corresponding to the selected predetermined program is displayed.

It is configured to have a display screen other than the travel map program, and the display screen of the straight target line T and the travel locus L, and the display screen of the material spray amount map program of the variable fertilizer rice transplanter and the field depth map program such as soil depth. And are configured to be selectively displayable, and for example, an automatic straight-ahead screen display and a variable fertilizer application screen display are switched and displayed by a switching operation. Then, the monitor of the tablet terminal 1000 can be utilized for visually confirming the fertilizer application work result and indirectly recognizing the difference in the height of the hard disk of the soil, and can be used in a multifunctional manner.

It may be configured to have a display screen other than the travel map program, and a touch switch unit for switching the screen display such as an icon on a touch panel may be provided in the screen of the tablet terminal 1000.

The display of the traveling locus L in the field may be automatically terminated based on a predetermined rule for determining that the vehicle has gone out of the field. Then, the guidance display by the straight target line T and the locus display by the traveling locus L are automatically changed, and the operation is easy.

For example, when the first reference point A and the second reference point B have not been acquired, for example, when the work has not started yet, a wide area field display is performed in which the field concerned and the surrounding fields are displayed. , The automatic change to the in-field guidance display of the field may be made based on the acquisition of the first reference point A.

As described above, in the state where the first reference point A and the second reference point B are recorded, the directions orthogonal to the straight reference line R (even if they are not orthogonal to each other, for example, they differ by a specified angle or more). There is planting at the orientation), and the first reference point A and the second reference point A and the second are based on the rule that the planting of three sides (planting of the headland) including one side parallel to the straight reference line R has been completed. A specification that erases the reference point B may be adopted. Then, it is expected that the burden on the operator will be reduced by automatic erasing.

The screen data of the traveling locus L may be recorded (saved) in the tablet terminal 1000 based on the operation of erasing the first reference point A and the second reference point B. Then, the actual data regarding the completion of the field planting can be recorded.

When starting automatic steering in a rice transplanter having an automatic steering function with a GNSS antenna 200 and a leveling rotor 63, even if the second reference point B is not determined as a position a predetermined distance away from the first reference point A, the traveling direction When the deviation angle from the target azimuth is within a predetermined range, automatic steering can be started based on the first reference point A and the target azimuth. That is, under the precondition that the target direction is known in advance and the direction of the traveling vehicle body 2 is the correct direction according to the target direction, even if the second reference point B is not determined, the first reference point A The straight-ahead reference line R can be created by using the X-coordinate and the Y-coordinate and the detection result of the directional sensor 204, and the automatic straight-ahead can be started immediately without teaching. Unlike the specification in which the straight target line T parallel to the straight reference line R is set according to the user's instruction at a predetermined interval, the straight target line T is planted in the headland without planting in the adjacent row. Even if it may not be necessary to display, there is no need for correction to erase the straight target line T that has been displayed unnecessarily.

When performing automatic steering in a rice transplanter having an automatic steering function with a GNSS antenna 200 and a ground leveling rotor 63, an alarm is given a certain distance before the ridge based on the measurement data of the operating distance of the ground leveling rotor 63 in the immediately preceding work line. After the alarm for a predetermined time, the engine 30 may not be stopped, but the HST servomotor 211 of the stepless speed changer 14 may be controlled to automatically decelerate and stop the traveling vehicle body 2. Then, when it is detected that the aircraft has reached the work end position where the planting of seedlings on the rice field is finished or the supply of seed paddy to the rice field is finished when approaching the ridge, it is different from the specification to notify. Since the pseudo distance can be measured by using the working distance of the leveling rotor 63 in the immediately preceding work line without planting in the work line, it is possible to similarly notify the approach to the ridge.

Within the management application that manages a travel map program that displays the straight target line and travel trajectory, a depth map program that displays the depth of the field (thickness of the surface soil), and a supply map program that indicates the increase or decrease in the supply of fertilizer and chemicals. By selecting a program with the program selection section (switching icon) and displaying a map for each of multiple pieces of information on the tablet terminal 1000, the operator can easily interfere with straight-ahead driving, and the hard board in the field associated with writing, etc. Since the point where the depth changes can be grasped, the course can be corrected to the straight traveling direction by manually operating the handle 35 at the corresponding place, and the occurrence of the deviation of the working position is prevented.

By being able to check the amount of fertilizer and chemicals supplied in the past for each field location, it becomes easier to measure the switching timing of the settings of the fertilizer application device 5 and the chemical spraying device, or the automatic change of the fertilizer and chemical supply amount is appropriate. It will be easier to determine whether it is being done, and the supply of fertilizers and chemicals will be optimized.

The control device 100 executes automatic straight-ahead control according to a predetermined steering member operation mode selected from a plurality of steering member operation modes related to the operation of the steering wheel 35 by the automatic steering device 205. The selection of the steering member operation mode is manually performed according to the user's instruction.

More specifically, in a rice transplanter having an automatic steering function with a GNSS antenna 200, a memory function for storing a plurality of steering control patterns for driving the steering actuator 206 with an optimum motor torque according to the soil quality and water depth is implemented. It is equipped with a setting device such as a mode change switch 100x (see FIG. 6) for the user to manually set the steering control pattern while looking at the display on the vehicle-mounted monitor.

The steering member operation mode may be automatically selected in conjunction with a predetermined work device operation mode selected from the plurality of work device operation modes related to the operation of the center float 62C.

More specifically, the selection of the steering member operation mode increases the dead zone width of the rotating potentiometer 64 of the center float 62C when the soil is hard, and increases the dead zone width of the rotating potentiometer 64 when the soil is soft. It is automatically performed in conjunction with the float sensitivity dial operation for adjusting the so-called float sensitivity according to the soil quality, which is reduced.

Then, the optimum steering control pattern can be set. Then, it is possible to eliminate the difference in the response speed of the front wheels 10 to the steering actuator 206 due to direct seeding in the multipurpose specification and switching at the planting portion of the working device 4.

Since the conditions for operating the handle 35 can be selected, the handle 35 can be properly operated by the automatic steering device 205 according to the difference in conditions such as the soil quality of the field and the presence or absence of water, and the difference in the machine to be operated. , Straight running is properly performed and work accuracy is improved.

When the working conditions of the working device 4 are changed, the operating conditions of the handle 35 are changed in conjunction with each other, so that the handle 35 can be properly operated by the automatic steering device 205. Work accuracy is improved.

The automatic steering device 205 has a steering actuator 206 that operates with a motor operating amount corresponding to an input pulse signal. The control device 100 executes control for stopping the automatic steering device 205 when the deviation of the motor operating amount with respect to the input pulse signal exceeds a predetermined level.

As shown in FIG. 18, which is a partial front view of the vicinity of the steering actuator 206 of the seedling transplanting machine according to the embodiment of the present invention, the automatic steering of the steering actuator 206 that operates the steering wheel 35 so as to make the traveling vehicle body 2 go straight. A torque generator 1801 is connected to the motor.

In an automatic steering rice transplanter or seeder equipped with a torque generator 1801 in which the handle 35 may be turned by an external force from the field, when a wheel derailment or the like occurs, the automatic steering motor receives an external force from the front wheel 10. Therefore, if the state of not rotating in synchronization with the input pulse signal continues for a certain period of time or more, the automatic steering is stopped. It is desirable that such an automatic steering motor is a stepping motor.

Increasing the current value by manual operation from the steering handle and stopping the automatic steering due to the increase in torque are effective technologies to improve safety, but the engine mounted on a normal automobile that is not moved from the side of the front wheel 10 It is sufficiently effective only for the torque generator of a small general-purpose gasoline engine called a non-road engine. On the other hand, the torque generator 1801 also improves safety when the automatic steering motor is out of step due to derailing or the like.

Then, when the motor or the sensor of the steering actuator 206 fails, the automatic steering may be stopped if the automatic steering motor does not rotate in synchronization with the input pulse signal for a certain period of time or longer. Then, the increase in the current value due to the manual operation from the steering handle and the stop of the automatic steering due to the increase in torque are effective when the steering is performed in the opposite direction to the automatic control steering by the manual operation. Safety is improved when the steering motor is out of step.

Further, when a manual operation occurs, the automatic steering may be stopped if the automatic steering motor does not rotate in synchronization with the input pulse signal for a certain period of time or longer. Then, the phenomenon that the working position shifts due to the automatic steering is suppressed.

When excessive torque is required for the steering actuator 206 due to the ground resistance applied to the front wheels 10 and the rotation amount of the motor of the steering actuator 206 becomes small with respect to the input pulse signal, the automatic steering device 205 is stopped to cause the steering actuator 206. Can be prevented from being damaged due to overload.

Further, since it can be determined that the front wheel 10 is in a situation where the steering cannot be steered in the automatic straight-ahead direction, it is possible to prevent the vehicle from traveling in a state where the actual traveling locus deviates from the straight-ahead target line T.

FIG. 19 (a) is a plan view of the seedling transplanting machine of another embodiment (No. 2) of the present invention, and is a side view of the seedling transplanting machine of another embodiment (No. 2) of the present invention. As shown in 19 (b), the GPS antenna 200 is arranged on the axis of the front wheel 10, and the GNSS antenna 200 is used to reduce the influence of the posture change caused by pitching and rolling on the side of the traveling vehicle body 2. The additional antenna stay member 1901 may be extended from the rolling direction as the stay.

Then, although the main body antenna stay member 1902 is extended so as to suppress the pitching direction, vibration is not likely to occur because the rolling direction is free, so that slight vibration in the rolling direction is suppressed and the accuracy of automatic straight-ahead control is improved. Can be improved.

The plan view of the seedling transplanting machine according to another embodiment (No. 3) of the present invention is shown in FIG. 20 (a), and the side view of the seedling transplanting machine according to another embodiment (No. 3) of the present invention. As shown in FIG. 20 (b), for safety when replenishing seedlings, an additional antenna stay member 2001 that also serves as a handrail may be extended to the outside of the floor step 33.

In the plan view, the additional antenna stay member 2001 is provided with front reinforcing arms 2002 from the central portion in the left-right direction of the machine to the left and right sides of the machine in a posture orthogonal to the traveling direction or in a posture toward the rear toward the left and right outside of the machine. The rear reinforcing arm 2003 is provided on the rear side of the machine body on the rear side of the front side reinforcing arm 2002, and the rear side reinforcing arm 2003 is provided on the rear side toward the left and right outside of the machine body at a steeper angle than the front side reinforcing arm 2002. The base of the rear reinforcing arm 2003 is arranged inside the machine body with respect to the front reinforcing arm 2002. Further, in the side view, the front reinforcing arm 2002 is in a posture substantially perpendicular to the floor step 33, and the rear reinforcing arm 2003 is in an inclined posture toward the rear side of the machine body from the upper side to the lower side.

Further, the front reinforcing arm 2002 and the rear reinforcing arm 2003 are connected by a connecting arm 2004 having a posture in the front-rear direction of the machine body and substantially parallel to the floor step 33. The connecting arm 2004 is set at a position substantially equal to or slightly higher than the seat surface of the work seat 41.

Further, as shown in FIGS. 20A and 20B, the front reinforcing arm 2002, the rear reinforcing arm 2003, and the connecting arm 2004 are combined in a truss structure having a shape close to a triangle.

As described above, the operator can select a portion of the front reinforcement arm 2002, the rear reinforcement arm 2003, and the connecting arm 2004 that is easy to grasp and maintain the posture according to the work place, so that the operator can maintain a relatively comfortable posture. This makes it possible to improve work efficiency and reduce fatigue.

Further, since the front reinforcing arm 2002 is located on the side of the work seat 41 and is arranged near the position where the worker gets on and off from the side of the traveling vehicle body 2, it can be used as a handrail when getting on and off. Getting on and off will be quicker and safety will be improved.

Further, by combining the front reinforcing arm 2002, the rear reinforcing arm 2003 and the connecting arm 2004 in a truss structure, the strength of the additional antenna stay member 2001 is improved.

Then, not only the slight vibration in the rolling direction can be suppressed and the accuracy of the automatic straight-ahead control can be improved, but also the safety at the time of seedling replenishment can be improved.

As shown in FIG. 21, which is a side view of the seedling transplanter of another embodiment (No. 4) of the present invention, a slight rotation of the work seat 41 is a rotation fulcrum under the work seat 41. A spring 2101 and a push sensor 2102 may be provided around the 2103 to allow the user in the front-rear direction, and the push sensor 2102 may detect whether or not the user is seated. If the user is not seated for 30 seconds or more while the traveling vehicle body 2 is moving, the traveling vehicle body 2 is stopped after sounding a warning sound for 5 seconds.

Then, based on the detection result of the push sensor 2102, it is possible not only to warn that it is dangerous to replenish the seedlings while moving away from the work seat 41, to stop the traveling vehicle body 2, but also to stop the spring. By utilizing the elastic force of 2101, it is possible to prevent the ride from becoming uncomfortable due to lifting from the work seat 41.

That is, not only the assurance of safety is improved at the time of replenishing seedlings, but also the riding comfort is improved.

The work vehicle in the present invention can prevent the reference position for straight-ahead travel from being acquired by erroneous operation, can suppress an increase in the number of parts, and can work on the ground with a work device traveling in a field and traveling on a traveling vehicle body. It is useful for the purpose of using it for work vehicles.

2 Traveling vehicle body 4 Work equipment 35 Handle 62C Center float 63 Leveling rotor 66 Leveling clutch 100 Control device 200 GPS antenna 205 Automatic steering device 206 Steering actuator 207 Automatic straight-ahead setting member 209 Work detection sensor 1000 Tablet terminal R Straight-line reference line A 1st standard Point B Second reference point T Straight target line L Travel locus

Claims (6)

The work equipment (4,62C, 63) attached to the vehicle body (2) and
The steering member (35) that steers the vehicle body (2) and
A position information acquisition device (200) that acquires the position information of the vehicle body (2), and
A user instruction member (207) that receives a user instruction for acquiring reference position information used when the vehicle body (2) goes straight, and a user instruction member (207).
A straight-ahead device (205) that operates the steering member (35) so as to make the vehicle body (2) go straight.
A control device (100) that executes automatic straight-ahead control for causing the straight-ahead device (205) to operate the steering member (35) based on the reference position information.
Equipped with
The control device (100) calculates a straight reference line (R) and a single or a plurality of straight target lines (T) parallel to the straight reference line (R) based on the reference position information, and performs wireless communication. By using this, the straight reference line (R) and the straight target line (T) can be displayed on the external information terminal (1000) mounted on the vehicle body (2).
The notification device (208) is activated to notify that the vehicle body (2) is close to the field edge and the automatic straight-ahead control needs to be terminated , but even if the notification device (208) is activated. If the automatic straight-ahead control cannot be terminated, the vehicle body (2) will move forward when the vehicle body (2) travels forward for a predetermined distance or a predetermined time after the notification device (208) is activated. It is automatically decelerated, and after the start of automatic deceleration, abrupt deceleration is performed once or multiple times at predetermined time intervals .
If an operation to stop traveling is detected while the automatic straight-ahead control is being executed, the control device (100) does not reflect the steering operation of the steering member (35), or the steering member (35). ) Is stopped, but the straight-ahead device (205) is not stopped even when the traveling is stopped. The reference position information corresponds to the first reference position information corresponding to the first reference point (A) where the straight reference line (R) starts and the second reference point (B) where the straight reference line (R) ends. The second reference position information to be used, and
When the first reference position information is acquired, the traveling locus (L) of the vehicle body (2) is displayed on the external information terminal (1000).
The automatic steering control device according to claim 1, wherein when the second reference position information is acquired, the straight target line (T) is displayed on the external information terminal (1000). A work clutch (66) that turns on and off the power transmitted to the work device (63), and
A work clutch sensor (209) for detecting an on / off state of the power transmitted to the work device (63) is provided.
The traveling locus (L) is displayed on the external information terminal (1000) when the on state of the power transmitted to the working device (63) is detected by the working clutch sensor (209). The automatic steering control device according to claim 2. The external information terminal (1000) has a traveling map program for displaying the straight reference line (R) and the straight target line (T), a field depth map program for displaying the depth of the field, and the field. A management application that can select a predetermined program from the material spray amount map program for displaying the spray amount of the material to be sprayed is installed, and the map corresponding to the selected predetermined program is displayed. The automatic steering control device according to any one of claims 1 to 3, wherein the automatic steering control device is displayed. The control device (100) is the automatic straight-ahead control according to a predetermined steering member operation mode selected from a plurality of steering member operation modes related to the operation of the steering member (35) by the straight-ahead device (205). And run
The automatic steering control device according to any one of claims 1 to 4, wherein the selection of the steering member operation mode is manually performed according to a user instruction. The straight-ahead device (205) has a steering step motor (206) that operates with a motor operating amount corresponding to an input pulse signal.
The control device (100) is characterized in that it executes control for stopping the straight-ahead device (205) when the deviation of the motor operating amount with respect to the input pulse signal exceeds a predetermined level. Item 4. The automatic steering control device according to any one of Items 1 to 5.

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