JP2018186762A - Working vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce reciprocating travels between an intermediate position of working travel and a levee-side when cargoes loaded on a traveling machine body or a working device have reduced on a working vehicle.SOLUTION: A working vehicle comprises a working device for performing a work on a field; a positioning unit for detecting a position of a traveling machine body 50; and an acquisition unit for acquiring work end positions D1-D7 positioned at a levee-side. The working vehicle further comprises a cargo detection unit for detecting a residual quantity of a prescribed cargo which is consumed along with working travels; and a cargo determination unit for detecting whether cargoes will become insufficient or not until the traveling machine body 50 reaches the work end position D1 from a present position K2 on the basis of the detection by the positioning unit and the cargo detection unit. When it is determined that cargoes will become insufficient until the traveling machine body 50 reaches the work end position D1 from the present position K2, a consumption suppression mode for suppressing consumption of cargoes is activated.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a work vehicle such as a riding type rice transplanter, a riding type direct seeder, or a tractor that supplies seedlings, seeds, fertilizers, drugs, and other materials to the rice field.

  In a riding type rice transplanter that is an example of a work vehicle, as disclosed in Patent Document 1, a seedling planting apparatus ( A work traveling for planting seedlings is carried out by a device corresponding to the working device. Next, when the traveling machine body reaches the other side, the work travel is interrupted, the turn at the other side is performed, and the next work travel is started from the other side toward the one side. , Repeating the running and turning.

  In Patent Document 1, a work travel line in which a traveling machine body travels while planting seedlings with a seedling planting device is set, and a positioning unit that detects the position of the traveling machine body is provided in the traveling machine body. Based on the above, a function for automatically maneuvering the traveling machine body is provided so that the traveling machine body automatically travels along the work traveling line.

  In the riding type rice transplanter such as Patent Document 1, the seedling planting device runs the seedling remaining amount sensor for detecting that the number of seedlings on the seedling stand (corresponding to the load) has decreased, and detection of the seedling remaining amount sensor. An informing device for informing the driver of the airframe is provided. The traveling machine body is provided with a reserve seedling stand, and a spare seedling is placed on the reserve seedling stand.

  Thus, when it is informed that the seedlings on the seedling table are low, the driver interrupts the work travel and stops the traveling machine, and supplies the seedlings on the seedling table. After this, the work travel is resumed.

JP 2008-92818 A

As described above, if the operation of replenishing the seedling on the reserve seedling table to the seedling platform is repeated, the seedling on the reserve seedling table will be lost.
For example, when there are no seedlings on the reserve seedling stand at the intermediate position of the work travel, the work travel is interrupted and the traveling machine body travels to the heel. The seedlings placed on the heel are replenished to the reserve seedling table at the end of the dredge, and when the replenishment of the seedling to the reserve seedling table is finished, the traveling machine body is moved to the position where the work travel was interrupted from the near end. , Resume working.

As described above, the reciprocating travel between the intermediate position of the work travel and the heel is merely moving the traveling machine body without performing work, so there is room for improvement in terms of improving work efficiency.
An object of the present invention is to reduce the reciprocal travel between the intermediate position of the work travel and the heel when the load mounted on the traveling machine body or the work device decreases in the work vehicle.

The work vehicle of the present invention is
A work device that performs work on the field, a positioning unit that detects a position of the traveling machine body, and an acquisition unit that acquires a work end position located on the heel,
A load detection unit for detecting a remaining amount of a predetermined load consumed as a result of working; and
Based on the detection of the positioning unit and the mounted object detection unit, the mounted object determination unit detects whether the mounted object is in a shortage before the traveling machine body reaches the work end position from the current position. And
When it is determined that the load is insufficient before the traveling machine body reaches the work end position from the current position, a consumption suppression mode is activated to suppress consumption of the load.

  If the work travel is continued at the intermediate position of the work travel, the consumption suppression mode is activated according to the present invention when the load becomes insufficient before the traveling machine body reaches the work end position.

Thereby, according to the present invention, it is possible to continue the work travel while suppressing the consumption of the load (while saving), and the load is insufficient before the traveling machine body reaches the work end position. The traveling machine body can travel to the work end position while avoiding this.
When the traveling machine body reaches the work end position, the traveling machine body is stopped at the work end position, and the load placed on the ridge may be mounted on the traveling machine body. Can be migrated without waste.

  As described above, according to the present invention, the work travel is interrupted at the intermediate position of the work travel, the travel machine body is traveled to the heel, and then the travel machine body is traveled from the heel to the position where the work travel is interrupted. Since it is less necessary to reciprocate between the intermediate position of work travel and the edge of the work travel, the work efficiency can be improved.

As the present invention,
The acquisition unit acquires a work start position and the work end position, and acquires a work travel line connecting the work start position and the work end position,
It is preferable that an automatic travel control unit for automatically maneuvering the traveling machine body is provided so that the traveling machine body travels along the work travel line based on the detection of the positioning unit.

  As disclosed in Patent Document 1, some work vehicles include an automatic travel control unit that performs automatic steering of a traveling machine body so that the traveling machine body travels along a work traveling line. In this case, if the work start position is acquired in addition to the work end position, the work travel line is obtained by connecting the work start position and the work end position.

  Thus, according to the present invention, the acquisition unit acquires the work start position, the work end position, and the work travel line so that the acquisition unit operates the consumption suppression mode, and the automatic travel control unit It is equipped with functions and can make efficient income.

As the present invention,
In the consumption suppression mode, it is preferable that the driver of the traveling machine body is informed that an operation for suppressing consumption of the mounted object should be performed.

  If the work travel is continued at the intermediate position of the work travel, if the load becomes insufficient before the traveling machine body reaches the work end position, according to the present invention, the consumption suppression mode is activated and the driver Is notified. As a result, the driver can perform an appropriate operation so that the consumption of the load is suppressed (so as to save).

As the present invention,
In the consumption suppression mode, it is preferable that an operation for suppressing consumption of the load is automatically performed.

  If the work travel is continued at the intermediate position of the work travel, if the load becomes insufficient before the traveling machine body reaches the work end position, according to the present invention, the consumption suppression mode is activated, Since the operation (conserved operation) that suppresses the consumption of power is automatically performed, the workability is improved.

As the present invention,
The working device is a seedling planting device for planting seedlings in a field, and the load is a seedling,
An operation for suppressing consumption of the load in the consumption suppression mode is as follows.
An operation of widening the seedling planting interval in the direction of travel of the traveling aircraft by the planting arm;
An operation of reducing the amount of seedling taken out from the seedling platform by the planting arm and reducing the vertical feeding amount of the seedling of the vertical feeding mechanism provided in the seedling platform;
An operation of slowing the lateral feed speed of the seedling platform;
It is preferable that the operation is at least one of the operations.

  According to the present invention, when a seedling planting device is provided as a working device, the consumption suppression mode is activated, so that consumption of seedlings by the seedling planting device can be appropriately suppressed (so as to be appropriately saved). Become).

As the present invention,
The working device is a supply device that supplies at least one of seeds, fertilizers and drugs to the field, and the load is at least one of seeds, fertilizers and drugs,
The operation for suppressing the consumption of the load in the consumption suppression mode is preferably an operation for reducing the supply amount of the supply device.

  According to the present invention, when the working device includes a supply device that supplies at least one of seeds, fertilizers, and medicines to the field, the consumption suppression mode is activated, so that the seeds, fertilizers, and medicines by the supply devices are activated. Consumption of at least one of them will be appropriately suppressed (save appropriately).

As the present invention,
The load is fuel supplied to the engine of the traveling aircraft;
An operation for suppressing consumption of the load in the consumption suppression mode is as follows.
An operation of operating the traveling transmission of the traveling machine body to a low speed side, an operation of operating an accelerator of the engine to a low speed side,
Of these, at least one of them is preferred.

  According to the present invention, fuel consumption by the engine is appropriately suppressed (appropriate savings) by operating the consumption suppression mode.

As the present invention,
In the consumption suppression mode, an operation limit of an operation for suppressing the consumption of the mounted object is set,
It is preferable that a manual changing unit capable of artificially changing the operation limit is provided.

As an example, a supply device that supplies fertilizer to the field will be described as a working device. If the supply of fertilizer by the supply device becomes too small due to the operation of the consumption suppression mode, the crop yield may be reduced. .
In this way, in order to avoid the possibility that the crop yield will be reduced, the work run is interrupted at the middle position of the work run, the running machine is run to the shore, and the fertilizer placed on the fence is replenished to the running machine Some judgments should be made.

According to the present invention, the work travel is interrupted at an intermediate position of the work travel, the traveling machine body is traveled to the edge and the load is replenished, and the work efficiency is reduced, and the load consumption is suppressed in the consumption restraint mode. Regarding the inconvenience associated with the operation, the driver may compare the decrease in work efficiency with the inconvenience and determine the allowable limit of the inconvenience.
Thus, the driver can set the operation limit of the operation for suppressing the consumption of the load in the consumption suppression mode so that the inconvenience does not exceed the allowable limit.

It is a whole side view of a riding type rice transplanter. It is a whole top view of a riding type rice transplanter. It is the schematic which shows the transmission system to a front wheel and a rear wheel, and the transmission system to a seedling planting apparatus. It is a figure which shows the cooperation state of a control apparatus and each part. It is a top view which shows the setting state of a work travel line and a turning line. In the 1st other form of implementation of invention, it is a figure which shows the cooperation state of a control apparatus and each part. In the 2nd another form of implementation of invention, it is a figure which shows the connection state of a control apparatus and each part.

In the embodiment of the present invention, a six-row planting type rice transplanter that is an example of a work vehicle that performs planting work in a farm field (paddy field) is shown.
The front-rear direction and the left-right direction in the embodiment of the present invention are described as follows unless otherwise specified. When the traveling machine body 50 travels, the forward traveling direction is “front”, and the backward traveling direction is “rear”. The direction corresponding to the right side is “right” and the direction corresponding to the left side is “left” based on the forward posture in the front-rear direction.

(Overall configuration of riding rice transplanter)
As shown in FIG. 1 and FIG. 2, the riding type rice transplanter drives the link mechanism 3 and the link mechanism 3 to be raised and lowered at the rear part of the traveling machine body 50 including the right and left front wheels 1 and the right and left rear wheels 2. A hydraulic cylinder 4 is provided, and a seedling planting device 5 (corresponding to a working device) is supported at the rear of the link mechanism 3.

  As shown in FIGS. 1 and 2, the seedling planting device 5 is rotatable to the right and left parts of the rear part of the planting transmission case 6 and the planting transmission case 6 arranged at predetermined intervals in the left-right direction. A rotating case 7 supported by the rotating case 7, a planting arm 8 provided at both ends of the rotating case 7, a float 9, a seedling base 10, a vertical feed mechanism 11 provided on each of the seedling surface 10a of the seedling base 10, etc. It has.

  As shown in FIGS. 1 and 2, a fertilizer application device 18 (corresponding to a work device) is provided across the traveling machine body 50 and the seedling planting device 5, and the fertilizer application device 18 includes a hopper 13, a feeding unit 14, A blower 15, a groove forming device 16, a hose 17 and the like are provided.

  As shown in FIGS. 1 and 2, a hopper 13 for storing fertilizer and three feeding parts 14 corresponding to two planting strips are provided on the rear side of the driver seat 12 in the traveling body 50. A blower 15 is provided on the left lateral outer side of the feeding portion 14. A groove forming device 16 is connected to the float 9 to provide six groove forming devices 16, and six hoses 17 are connected across the feeding portion 14 and the groove forming device 16.

(Transmission system for front and rear wheels)
As shown in FIGS. 1 and 3, the power of the engine 31 provided at the front of the traveling machine body 50 is transmitted to a hydrostatic continuously variable transmission 33 (corresponding to a traveling transmission) via a transmission belt 32. Is done. The power of the continuously variable transmission 33 is transmitted from the gear transmission type auxiliary transmission 35 inside the transmission case 34 to the right and left front wheels 1 via the front wheel differential device 41.

  As shown in FIGS. 1 and 3, the power of the auxiliary transmission 35 is transmitted to the transmission shaft 39 of the rear axle case 37 via the transmission shaft 36, and to the right and left via the right and left side clutches 40. It is transmitted to the left rear wheel 2. A brake 38 capable of braking the transmission shaft 36 is provided inside the transmission case 34, and the front wheel 1 and the rear wheel 2 can be braked by the brake 38.

  As shown in FIGS. 1, 2, and 4, a steering handle 20 is provided on the front side of the driver seat 12, and a shift lever 45 is provided on the left side of the steering handle 20. By means of the shift lever 45, the continuously variable transmission 33 can be operated steplessly from the neutral position N to the forward side F and the reverse side R.

As shown in FIGS. 1, 2, and 3, by operating the steering handle 20, the right and left front wheels 1 can be steered from the straight travel position over the right and left steering limits.
The right and left side clutches 40 are of a frictional multi-plate type and are urged in a transmission state by springs (not shown), and the steering handle 20 and the right and left side clutches 40 are connected to a connecting rod (not shown). ) Mechanically connected.

  As shown in FIGS. 1, 2, and 3, when the right and left front wheels 1 are steered straight, and when the steering operation is performed within the range of right and left set angles from the straight travel position, the right and left side clutches 40 are It is operated to the state. Accordingly, the traveling machine body 50 moves forward (reverse) in a state where power is transmitted to the right and left front wheels 1 and the right and left rear wheels 2 (the transmission state of the right and left side clutches 40).

As shown in FIGS. 1, 2, and 3, when the right and left front wheels 1 are steered to the right steering limit side beyond the right set angle, the right side clutch 40 is manipulated to the disengaged state. The
Thus, power is transmitted to the right and left front wheels 1 and the left rear wheel 2 (turning outside) (the transmission state of the left side clutch 40), and the right rear wheel 2 (turning center side) (the right side clutch). The traveling machine body 50 turns to the right in the state of free rotation of the 40 interruption state.

As shown in FIGS. 1, 2 and 3, when the right and left front wheels 1 are steered to the left steering limit side beyond the left set angle, the left side clutch 40 is manipulated to the disengaged state. The
Accordingly, power is transmitted to the right and left front wheels 1 and the right rear wheel 2 (turning outside) (the transmission state of the right side clutch 40), and the left rear wheel 2 (turning center side) (left side clutch). The traveling machine body 50 turns to the left in the state of free rotation of the 40 disconnection state.

  As shown in FIGS. 1, 2 and 3, when the right and left front wheels 1 are steered from the right (left) steering limit side to the right (left) set angle to the straight drive position side, The right (left) side clutch 40 that has been operated to the state is operated to the transmission state, and the right and left side clutches 40 are returned to the state that has been operated to the transmission state.

(Power transmission system to seedling planting equipment)
As shown in FIGS. 1 and 3, in the transmission case 34, the power branched from immediately before the auxiliary transmission 35 is planted through the back clutch 29, the inter-strain transmission 42, the planting clutch 26, and the PTO shaft 43. Is transmitted to the device 5. As shown in FIG. 4, an electric motor 28 is provided to operate the planting clutch 26 in a transmission state and a cutoff state, and the electric motor 28 is operated by the control device 23.

  As shown in FIG. 3, the power transmitted to the seedling planting device 5 branches into two systems and is transmitted to the rotating case 7 and the lateral feed transmission device 44. The rotating case 7 is rotationally driven by the power transmitted to the rotating case 7, and the planting arm 8 is planted. With the power transmitted to the lateral feed transmission 44, a lateral feed shaft (not shown) is rotationally driven, and the seedling table 10 is driven to reciprocate laterally feed by the lateral feed shaft.

  As shown in FIGS. 3 and 4, the transmission lever 45 and the back clutch 29 are mechanically connected. When the transmission lever 45 is operated to the neutral position N and the forward side F, the back clutch 29 is operated to the transmission state, and when the transmission lever 45 is operated to the reverse side R, the back clutch 29 is operated to the disconnected state. .

  As shown in FIGS. 1 and 2, when the planting clutch 26 is operated in the transmission state, the rotary case 7 is rotationally driven as the seedling setting table 10 is reciprocally driven to the left and right. The planting arms 8 alternately take out the seedlings from the bottom of the resting table 10 and plant them in the field. When the seedling platform 10 reaches the right and left ends of the reciprocating lateral feed drive, the vertical feed mechanism 11 is operated to feed the seedlings on the seedling platform 10 downward. When the planting clutch 26 is operated in the disconnected state, the seedling bed 10 and the rotating case 7 are stopped.

(Drive system for fertilizer application)
As shown in FIG. 4, in the fertilizer application device 18, the feeding unit 14 is driven by the feeding motor 54, and the feeding motor 54 is operated by the control device 23. When the planting clutch 26 is operated in the transmission state, the feeding motor 54 is operated, and when the planting clutch 26 is operated in the disconnected state, the feeding motor 54 is stopped.

  As shown in FIGS. 1 and 2, when the feeding unit 14 is driven by the feeding motor 54, the fertilizer is fed from the hopper 13 by a predetermined amount by the feeding unit 14, and the fertilizer passes through the hose 17 by the blower 15. The grooving device 16 is supplied, and the fertilizer is supplied to the field through the grooving device 16.

(Automatic lifting control of seedling planting device)
As shown in FIG. 4, the rear part of the center float 9 is supported around the horizontal axis P <b> 1 of the seedling planting device 5 so as to be swingable up and down. A potentiometer type height sensor 22 for detecting the height of the center float 9 with respect to the seedling planting device 5 is provided, and a detection value of the height sensor 22 is input to the control device 23. As the traveling machine body 50 advances, the center float 9 follows the ground to the field, and the height from the field (center float 9) to the seedling planting device 5 is detected by the detected value of the height sensor 22. be able to.

As shown in FIG. 4, the hydraulic cylinder 4 is provided with a control valve 24 for supplying and discharging hydraulic oil, and the control valve 24 is operated by the control device 23.
In the operating state of the automatic lifting control, the control valve 24 is operated based on the height from the field to the seedling planting device 5 so that the seedling planting device 5 is maintained at the set height from the field, and the hydraulic pressure is controlled. The cylinder 4 expands and contracts, and the seedling planting device 5 automatically moves up and down. Thereby, the planting depth of the seedling is maintained at the set depth.

(Configuration for detecting the position of the traveling aircraft and the orientation of the traveling aircraft)
As shown in FIG. 1 and FIG. 2, right and left support frames 19 are provided on the right and left portions of the front portion of the traveling machine body 50, and a preliminary seedling stand 21 is supported on the support frame 19. . A support frame 25 is connected over the upper portions of the right and left support frames 19.

  As shown in FIGS. 1 and 2, a measuring device 30 (corresponding to a positioning unit) is attached to a portion of the support frame 25 that is positioned at the left and right center CL of the traveling machine body 50 in plan view. The measuring device 30 includes a receiving device (not shown) that acquires position information by a satellite positioning system, and an inertial measuring device (not shown) that detects the inclination (pitch angle, roll angle) of the traveling machine body 50. The measuring device 30 outputs positioning data indicating the position of the traveling machine body 50.

  As shown in FIGS. 1 and 2, an inertia measuring device 48 that measures inertia information is attached to a portion of the rear axle case 37 that is positioned at the left and right center CL of the traveling machine body 50 in plan view. The inertial measurement of the inertial measurement device 48 and the measurement device 30 is configured by an IMU (Internal Measurement Unit).

  A typical example of the above-described satellite positioning system (GNSS) is a GPS (Global Positioning System). The GPS uses a plurality of GPS satellites that orbit the earth, a control station that tracks and controls the GPS satellites, and a receiver that is included in the object to be measured (the traveling vehicle body 50). The position of the device is measured.

The inertial measurement device 48 includes a gyro sensor (not shown) that can detect the angular velocity of the yaw angle of the traveling machine body 50 (the turning angle of the traveling machine body 50), and an acceleration sensor that detects acceleration in three axial directions orthogonal to each other. (Not shown). The inertia information measured by the inertial measurement device 48 includes azimuth change information detected by the gyro sensor and position change information detected by the acceleration sensor.
Thereby, the position of the traveling machine body 50 and the orientation of the traveling machine body 50 are detected by the measuring device 30 and the inertial measuring device 48.

(Configuration related to automatic driving of the vehicle)
As shown in FIG. 4, the operation position of the shift lever 45 is input to the control device 23. A steering motor 51 for operating the steering handle 20 is provided, and a transmission motor 53 for operating the transmission lever 45 is provided.

  As shown in FIG. 4, a work travel line acquisition unit 61 (corresponding to an acquisition unit), a turn line acquisition unit 62, an automatic travel control unit 63, and an automatic turn control unit 64 are provided in the control device 23 as software.

  As shown in FIGS. 2 and 4, a push button type operation unit 52 that artificially operates the automatic traveling control unit 63 and the automatic turning control unit 64 in an activated state and a stopped state is provided in a grip portion of the transmission lever 45. The operation signal of the operation unit 52 is input to the control device 23. A display device 27 composed of a liquid crystal display or the like is provided on the front side of the steering handle 20.

(Setting of work travel line and turning line)
In the control device 23, the work travel lines L01 to L07 and the turning lines LL1 to LL6 are set as described below.
Alternatively, in the external control device (not shown), the work travel lines L01 to L07 and the turn lines LL1 to LL6 are set as described below, and the set work travel lines L01 to L07 and the turn line are set. The control device 23 acquires LL1 to LL6.

  As shown in FIG. 5, for example, in a field provided with ridges B1, B2, B3, and B4, the ridgeline B11, B21 is based on the position data of the ridgeline B11, B21, B31, B41 of the ridges B1 to B4. The headland lines LA1 and LA2 are set along the border lines B11 and B21 at a position on the center side of the field by the width of the traveling machine body 50 (the seedling planting device 5). The headland lines LB1 and LB2 are set along the heel line B31 and B41 at the position on the center side of the field by the lateral width of the traveling machine body 50 (the seedling planting device 5) from the heel line B31 and B41.

  As shown in FIG. 5, the work travel lines L01, L02, L03, L04, L05, L06, and L07 are parallel to the headland lines LB1 and LB2 and have a predetermined interval W1 (travel machine body 50 (seed planting device 5 ) Is set across the headland lines LA1 and LA2 so that they are parallel to each other, and the directions of the work travel lines L01 to L07 (see arrows of the work travel lines L01 to L07 shown in FIG. 5) are set. Is set.

  As shown in FIG. 5, the start end portions (one end portion) of the work travel lines L01 to L07 are the work start positions C1, C2, C3, C4, C5, C6, and C7. The end portions (the other end portions) of the work travel lines L01 to L07 are work end positions D1, D2, D3, D4, D5, D6, and D7. Thereby, what connected work start position C1-C7 and work end position D1-D7 becomes work run lines L01-L07.

  As shown in FIG. 5, a circular turning line LL1 in a plan view is set in the field so as to connect the work end position D1 and the work start position C2. Similarly, work end position D2 and work start position C3, work end position D3 and work start position C4, work end position D4 and work start position C5, work end position D5 and work start position C6, work end position D6 and work start. Circular turning lines LL2, LL3, LL4, LL5, and LL6 in a plan view are set so as to connect the position C7.

  On the display device 27, work start positions C1 to C7 and work end positions D1 to D7, work travel lines L01 to L07, turning lines LL1 to LL6, and the position of the traveling machine body 50 by the measuring device 30 are displayed on the display device 27 (see FIG. 4). When the driver determines that there is no problem, the driver presses an approval button (not shown).

  Thereby, the position data of the work travel lines L01 to L07, the work start positions C1 to C7, and the work end positions D1 to D7 are acquired and stored in the work travel line acquisition unit 61 as position data. At the same time, the turning lines LL1 to LL6 are acquired and stored in the turning line acquisition unit 62 as position data.

(Automatic traveling of the aircraft)
As described above (setting of the work travel line and the turning line), in the state where the work travel lines L01 to L07 and the turning lines LL1 to LL6 are set, the traveling machine body 50 is started as shown in FIG. In a state where the driver is positioned at the position K1, the driver operates the operation unit 52 to start working.

  As described below, the automatic travel control unit 63 operates the speed change lever 45 (transmission motor 53) to a predetermined speed change position so that the travel machine body 50 travels along the work travel lines L01 to L07 ( The steering handle 20 (steering motor 51) is operated so that the position of the measuring device 30 is positioned on the work travel lines L01 to L07.

  As described below, the automatic turning control unit 64 operates the speed change lever 45 (transmission motor 53) to a predetermined low speed position so that the traveling machine body 50 travels along the turning lines LL1 to LL6 (measurement). The steering handle 20 (steering motor 51) is operated so that the position of the device 30 is located on the turning lines LL1 to LL6.

  As shown in FIG. 5, at the work start positions C1 to C7, the seedling planting device 5 is lowered to the field, and the seedling planting device 5 is in an operating state of automatic lifting control. The planting clutch 26 is operated to the transmission state, the feeding motor 54 is activated, and seedling planting by the seedling planting device 5 and supply of fertilizer by the fertilizer application device 18 are started.

  At the same time, as shown in FIG. 5, based on the detection of the measuring device 30 and the inertial measuring device 48, the automatic traveling control unit 63 performs the automatic steering operation of the front wheels 1, and the traveling vehicle body 50 is It travels automatically along the work travel lines L01 to L07, and seedling planting by the seedling planting device 5 and fertilizer supply by the fertilizer application device 18 are performed.

  As shown in FIG. 5, when the traveling machine body 50 reaches the work end positions D1 to D7, the planting clutch 26 is operated in a disconnected state, the feeding motor 54 is stopped, and the automatic raising / lowering control of the seedling planting device 5 is performed. It will be in a stop state and the seedling planting device 5 will be raised from the field.

  At the same time, as shown in FIG. 5, based on the detection of the measuring device 30 and the inertial measuring device 48, the automatic turning control unit 64 performs an automatic steering operation of the front wheels 1, and the traveling machine body 50 is It automatically travels along the turning lines LL1 to LL6.

  As shown in FIG. 5, when the traveling machine body 50 reaches the work start positions C <b> 1 to C <b> 7 from the turning lines LL <b> 1 to LL <b> 6, as described above, the seedling planting device 5 is lowered to the field and the seedling planting device 5 The automatic lift control is activated. The planting clutch 26 is operated to the transmission state, the feeding motor 54 is activated, and seedling planting by the seedling planting device 5 and supply of fertilizer by the fertilizer application device 18 are started.

  At the same time, as shown in FIG. 5, based on the detection of the measuring device 30 and the inertial measuring device 48, the automatic traveling control unit 63 performs the automatic steering operation of the front wheels 1, and the traveling vehicle body 50 is It travels automatically along the work travel lines L01 to L07, and seedling planting by the seedling planting device 5 and fertilizer supply by the fertilizer application device 18 are performed.

(Construction regarding the inter-strain transmission for consumption of seedlings)
As shown in FIG. 4, a stock motor 71 for operating the stock transmission 42 and a stock sensor 72 for detecting the shift position of the stock transmission 42 are provided. The inter-stock motor 71 is operated by the control device 23, and the detection value of the inter-stock sensor 72 is input to the control device 23.

  As shown in FIGS. 1 and 3, when the inter-strain transmission device 42 is operated to the low speed side, the rotational speed of the rotating case 7 becomes low, and the planting interval of the seedlings in the traveling direction of the traveling machine body 50 by the planting arm 8 is increased. Become wider. When the inter-strain transmission device 42 is operated to the high speed side, the rotational speed of the rotary case 7 is increased, and the seedling planting interval in the traveling direction of the traveling machine body 50 by the planting arm 8 is reduced. By detecting the shift position of the inter-strain transmission device 42 with the inter-strain sensor 72, the planting interval of the seedlings in the traveling direction of the traveling machine body 50 by the planting arm 8 can be detected.

  As shown in FIG. 3, a stock transmission 42 is arranged on the lower side of the continuously variable transmission 33. Even if the continuously variable transmission 33 is operated and the traveling speed of the traveling machine body 50 is changed, the rotational speed of the rotating case 7 is also changed in conjunction with this. The planting interval of the seedlings does not change.

  As shown in FIG. 4, a planting interval setting unit 46 is provided in the traveling machine body 50, and a signal from the planting interval setting unit 46 is input to the control device 23. The planting interval setting unit 46 is a dial operation type. When the driver operates the planting interval setting unit 46, the inter-organization transmission 71 is operated by the inter-organization motor 71, and the traveling body 50 of the planting arm 8 is operated. The seedling planting interval in the traveling direction can be set arbitrarily.

(Concerning the consumption of seedlings, the configuration regarding the amount of seedlings taken out from the seedling stand by the planting arm in the vertical direction)
As shown in FIG. 4, the removal amount motor 73 for changing the amount of removal of the seedling from the seedling platform 10 by the planting arm 8 in the vertical direction, and the vertical direction of the seedling from the seedling platform 10 by the planting arm 8. And a take-out amount sensor 74 for detecting the take-out amount. The removal amount motor 73 is operated by the control device 23, and the detection value of the removal amount sensor 74 is input to the control device 23.

The take-out amount motor 73 changes the position of the seedling raising table 10 up and down with respect to the rotation trajectory of the planting arm 8.
If the position of the seedling platform 10 is changed to the upper side with respect to the rotation trajectory of the planting arm 8, the area below the seedling platform 10 through which the planting arm 8 passes becomes shorter in the vertical direction. The amount of the seedling taken out from the seedling placing base 10 by 8 in the vertical direction is reduced.
If the position of the seedling platform 10 is changed to the lower side with respect to the rotation trajectory of the planting arm 8, the lower region of the seedling platform 10 through which the planting arm 8 passes becomes long in the vertical direction. The amount of the seedling taken out from the seedling table 10 by the arm 8 in the vertical direction increases.

The position of the seedling setting base 10 with respect to the rotation trajectory of the planting arm 8 and the vertical feed amount of the seedling of the vertical feed mechanism 11 are linked.
When the amount of seedlings taken out from the seedling table 10 by the planting arm 8 in the vertical direction decreases, the vertical feed amount of the seedlings by the vertical feeding mechanism 11 decreases, and the seedlings from the seedling table 10 by the planting arm 8 decrease. When the removal amount in the vertical direction increases, the vertical feed amount of the seedling of the vertical feed mechanism 11 increases.

  The removal amount sensor 74 detects the position of the seedling platform 10 with respect to the rotation trajectory of the planting arm 8. Based on the detection value of the removal amount sensor 74, the removal amount in the vertical direction of the seedlings from the seedling table 10 by the planting arm 8 can be detected.

  As shown in FIG. 4, a takeout amount setting unit 47 is provided in the traveling machine body 50, and a signal from the takeout amount setting unit 47 is input to the control device 23. The take-out amount setting unit 47 is a dial operation type. When the driver operates the take-out amount setting unit 47, the take-out amount motor 73 is operated to move the seedlings from the seedling table 10 by the planting arm 8 in the vertical direction. The amount to be taken out can be set arbitrarily.

(Construction related to lateral transmission for consumption of seedlings)
As shown in FIG. 4, a lateral feed motor 75 for operating the lateral feed transmission device 44 and a lateral feed sensor 76 for detecting a shift position of the lateral feed transmission device 44 are provided. The lateral feed motor 75 is operated by the control device 23, and the detection value of the lateral feed sensor 76 is input to the control device 23.

  When the lateral feed transmission 44 is operated to the low speed side, the lateral feed speed of the seedling platform 10 becomes low, and the area under the seedling platform 10 through which the planting arm 8 passes becomes shorter in the left-right direction. The amount of the seedling taken out from the seedling table 10 by the attached arm 8 in the left-right direction is reduced.

  When the lateral feed transmission 44 is operated to the high speed side, the lateral feed speed of the seedling platform 10 is increased, and the lower area of the seedling platform 10 through which the planting arm 8 passes becomes longer in the left-right direction. The amount of the seedling taken out from the seedling table 10 by the attached arm 8 in the left-right direction increases. By detecting the shift position of the lateral feed transmission device 44 with the lateral feed sensor 76, it is possible to detect the amount of seedling taken out from the seedling platform 10 by the planting arm 8 in the left-right direction.

  As shown in FIG. 4, a lateral feed setting unit 49 is provided in the traveling machine body 50, and a signal from the lateral feed setting unit 49 is input to the control device 23. The lateral feed setting unit 49 is a dial operation type. When the driver operates the lateral feed setting unit 49, the lateral feed motor 75 is operated, and the right and left direction of the seedlings from the seedling setting table 10 by the planting arm 8. The amount to be taken out can be set arbitrarily.

(Explanation on seedling supply)
In the riding type rice transplanter, as seedlings are planted and fertilizer is supplied, the seedling planting device 5 consumes less seedlings (corresponding to the loaded items) of the seedling platform 10 and fertilizes. In the device 18, the fertilizer (corresponding to the load) in the hopper 13 is consumed and decreased, and the fuel (corresponding to the load) in the fuel tank (not shown) is decreased.

  As shown in FIGS. 1, 2, and 5, when the traveling machine body 50 is positioned on the work traveling lines L01 to L07, the work traveling is interrupted when the number of seedlings on any of the seedling placing surfaces 10a of the seedling placing platform 10 is reduced. Thus, the traveling machine body 50 is stopped at the positions of the work traveling lines L01 to L07, and the seedlings on the reserve seedling placing table 21 are replenished to the seedling placing surface 10a of the seedling placing stand 10, and then the work traveling is resumed. .

As shown in FIGS. 1, 2, and 5, when the traveling machine body 50 is positioned on the work traveling lines L01 to L07 and the seedlings on the reserve seedling platform 21 are consumed, the work traveling is interrupted and the traveling machine body 50 is operated. The vehicle travels from the position of the travel lines L01 to L07 to the shore.
At the time of dredging, the seedlings placed on the collars B1 to B4 are replenished to the preliminary seedling setting table 21, and when the replenishment of the seedlings to the preliminary seedling setting table 21 is finished, the traveling of the traveling machine body 50 is interrupted from the corner. The work travel is resumed by traveling to the positions of the work travel lines L01 to L07.

(Operation related to suppression of seedling consumption) (Consumption suppression mode does not work)
In order to reduce the reciprocal travel between the positions of the work travel lines L01 to L07 where the work travel is interrupted and the heel as described in the previous section (explanation regarding seedling replenishment), the consumption suppression mode is activated by the control device 23. Sometimes. First, a state where the consumption suppression mode is not activated will be described.

As shown in FIG. 4, the control device 23 includes a seedling detection unit 65 (corresponding to a load detection unit) and a seedling determination unit 66 (corresponding to a load determination unit) as software.
Each of the preliminary seedling bases 21 is provided with a preliminary seedling sensor 55 for detecting the presence or absence of seedlings, and the length (amount of seedlings) of the seedlings is detected on each of the seedling setting surfaces 10a of the seedling base 10. A seedling remaining amount sensor 56 is provided, and detection values of the preliminary seedling sensor 55 and the seedling remaining amount sensor 56 are input to the control device 23.

As shown in FIG. 5, it is assumed that the current position of the traveling machine body 50 is the position K2 of the work traveling line L01.
Based on the detection by the measuring device 30, a distance E1 from the position K2 to the work end position D1 is detected. Based on the detection value of the reserve seedling sensor 55 and the detection value of the seedling remaining amount sensor 56, the seedling detection unit 65 detects the seedling amount of the seedling setting table 10 and the reserve seedling setting table 21 at the position K 2.

When the planting interval between the seedlings in the traveling direction of the traveling machine body 50 by the planting arm 8 is detected by the inter-strain sensor 72, based on the distance E1, the seedling determination unit 66 moves the position from the position K2 to the work end position D1. The number of seedlings planted by the planting arm 8 is detected.
When the removal amount sensor 74 and the lateral feed sensor 76 detect the removal amount of the seedling in the upward direction and the left-right direction from the seedling placing base 10 by the planting arm 8, the seedling determination unit 66 causes the planting arm 8 to The amount of seedling at one time when the seedling is planted is detected.

  Based on the number of seedlings planted as described above and the amount of seedlings at one time when the planting arm 8 plants the seedlings (for 6 strips), from the seedling determination unit 66, from the position K2 to the work end position D1. The total amount of seedling consumed is detected.

The seedling determination unit 66 compares the seedling amount of the seedling setting table 10 and the preliminary seedling setting table 21 at the position K2 with the total amount of seedlings consumed from the position K2 to the work end position D1.
When it is determined that the amount of seedlings on the seedling setting stand 10 and the reserve seedling setting stand 21 at the position K2 is larger than the total amount of seedlings consumed from the position K2 to the work end position D1, the traveling machine body 50 operates from the position K2. It is determined that there is no shortage of seedlings before reaching the end position D1.

  As a result, the work travel is continued without operating the consumption suppression mode. The determination as to whether or not to activate the consumption suppression mode by the seedling determination unit 66 is repeatedly performed each time the traveling machine body 50 travels a predetermined distance.

  During this time, when the seedlings on any seedling surface 10a of the seedling platform 10 are reduced, the work travel is interrupted, the traveling machine body 50 is stopped in the middle of the work travel line L01, and the seedlings on the preliminary seedling platform 21 are removed. The above-described seedling setting surface 10a of the seedling setting table 10 is replenished, and then the work travel is resumed.

(Operations related to suppression of seedling consumption) (Consumption suppression mode is activated)
As shown in FIG. 5, in the state where the current position of the traveling machine body 50 is the position K2 of the work traveling line L01, the seedling determination unit 66 determines the seedling amount of the seedling raising table 10 and the spare seedling setting table 21 at the position K2. If it is determined that the amount is less than the total amount of seedlings consumed from the position K2 to the work end position D1, it is determined that the seedlings are in a shortage before the traveling machine body 50 reaches the work end position D1 from the position K2. .

Thus, the consumption suppression mode is activated, and the display device 27 displays that the consumption suppression mode has been activated.
As shown in FIG. 5, the traveling machine body 50 is positioned by comparing the amount of seedlings of the seedling setting table 10 and the preliminary seedling setting table 21 at the position K2 with the total amount of seedlings consumed from the position K2 to the work end position D1. At least one of the following operations (1-1), (1-2), and (1-3) is automatically performed so that the seedling does not become insufficient before reaching the work end position D1 from K2. Done.

(1-1) The inter-plant transmission device 42 is automatically operated to the low-speed side by the inter-plant motor 71, and the planting interval of the seedlings in the traveling direction of the traveling machine body 50 by the planting arm 8 is the planting interval setting unit 46. It becomes wider than the value set by.

(1-2) The position of the seedling platform 10 with respect to the rotation trajectory of the planting arm 8 is automatically changed to the upper side by the take-out amount motor 73, and the seedling from the seedling platform 10 by the planting arm 8 is changed in the vertical direction. Is less than the value set by the extraction amount setting unit 47.

(1-3) The lateral feed transmission device 44 is automatically operated to the low speed side by the lateral feed motor 75, and the amount of the seedling taken out from the seedling platform 10 by the planting arm 8 is set to the lateral feed setting. The value is smaller than the value set by the unit 49.

As shown in FIG. 4, the traveling machine body 50 is provided with a manual change unit 57, and a signal from the manual change unit 57 is input to the control device 23.
When the driver operates the manual changing unit 57, when the consumption suppression mode is activated by the control device 23, which of the above-described (1-1), (1-2), and (1-3) is performed. It is possible to select in advance whether or not to be displayed.

In this case, one of the above-mentioned (1-1), (1-2), and (1-3) is selected, or the above-mentioned (1-1), (1-2), and (1-3) are selected. Any two of these can be selected, or all the above-mentioned (1-1), (1-2), and (1-3) can be selected.
Which of the above-described (1-1), (1-2), and (1-3) is being performed is displayed on the display device 27 in the state where the consumption suppression mode is activated.

As described above, the work travel is continued while the operations (1-1), (1-2), and (1-3) described above are performed in the state in which the consumption suppression mode is activated.
During this time, when the seedlings on any seedling surface 10a of the seedling platform 10 are reduced, the work travel is interrupted, the traveling machine body 50 is stopped in the middle of the work travel line L01, and the seedlings on the preliminary seedling platform 21 are removed. The above-described seedling setting surface 10a of the seedling setting table 10 is replenished, and then the work travel is resumed.

  As shown in FIG. 5, when the traveling machine body 50 reaches the work end position D1, the driver stops the traveling machine body 50 and replenishes the seedlings 21 and the seedling platform 10 with seedlings placed on the ridge B1. To do. When the replenishment of the seedlings to the reserve seedling platform 21 and the seedling platform 10 is finished, the traveling machine body 50 is traveled to the work start position C2, and the work travel of the next work travel line L02 is started.

(Operation limit setting by manual change part)
As described above, when the inter-strain transmission device 42 is operated too slowly when the consumption suppression mode is activated, the seedling planting interval in the traveling direction of the traveling machine body 50 by the planting arm 8 becomes too wide. There is.
When the position of the seedling platform 10 is changed to the upper side with respect to the rotation trajectory of the planting arm 8 or the lateral feed transmission device 44 is operated to the low speed side, the planting arm 8 is used for planting seedlings. The amount of seedlings may be too small.

  In this case, the manual change unit 57 causes the operation limit to the low speed side of the inter-variety transmission 42 in the state in which the consumption suppression mode is activated, and the change limit to the upper side of the position of the seedling platform 10 with respect to the rotation trajectory of the planting arm 8. The operation limit to the low speed side of the lateral feed transmission 44 can be arbitrarily set and changed independently of each other.

  When the operation as described above is performed by the manual change unit 57, the operation to the low speed side of the inter-variety transmission device 42 is stopped at the operation limit in the state where the consumption suppression mode is activated, or the rotation trajectory of the planting arm 8 When the change to the upper side of the position of the seedling platform 10 is stopped at the change limit, or the operation to the low speed side of the lateral feed transmission device 44 is stopped at the operation limit, the traveling machine body 50 is moved to the work end position D1. Until reaching D7, seedlings may be in shortage.

  In the state as described above, the display device 27 displays that seedlings are in shortage. As a result, the work travel is interrupted and the traveling machine body 50 is traveled from the position of the work travel lines L01 to L07 to the heel, and the seedlings placed on the heels B1 to B4 at the heel are put on the reserve seedling table 21 and the seedlings. The base 10 is replenished, and the traveling machine body 50 is caused to travel to the positions of the work traveling lines L01 to L07 where the work traveling is interrupted from the heel and the working traveling is resumed.

(First embodiment of the invention)
In the above-mentioned (form for inventing), you may apply consumption suppression mode to the fertilizer application apparatus 18 as the following description.

As shown in FIGS. 1, 2, and 5, when the traveling machine body 50 is positioned on the work traveling lines L01 to L07 and the fertilizer in the hopper 13 is reduced in the fertilizer application apparatus 18, the traveling work is interrupted and the traveling machine body 50 is stopped. Is traveled from the position of the work travel lines L01 to L07 to the heel.
At the heel, the fertilizer placed on the ridges B1 to B4 is replenished to the hopper 13, and when the replenishment of the fertilizer to the hopper 13 is finished, the work travel lines L01 to the work travel line L01 to which the work travel is interrupted from the heel. The work travel is resumed by traveling to the position of L07.

As shown in FIG. 6, in the fertilizer application device 18, the feeding unit 14 is driven by the feeding motor 54, and the feeding amount (supply amount) of the feeding unit 14 is changed by changing the rotation speed of the feeding motor 54. can do.
A fertilizer setting unit 58 is provided in the traveling machine body 50, and a signal from the fertilizer setting unit 58 is input to the control device 23. The fertilizer setting unit 58 is a dial operation type, and the driver can arbitrarily set the feeding amount of the feeding unit 14 by operating the fertilizer setting unit 58.

  As shown in FIG. 6, a fertilizer sensor 67 (corresponding to a load detection unit) that detects the amount of fertilizer in the hopper 13 is provided, and a detected value of the fertilizer sensor 67 is input to the control device 23. As a software, a fertilizer determination unit 68 (corresponding to a load determination unit) is provided in the control device 23.

(Operation related to suppression of fertilizer consumption) (Consumption suppression mode does not work)
As shown in FIG. 5, it is assumed that the current position of the traveling machine body 50 is the position K2 of the work travel line L01 and the distance E1 from the position K2 to the work end position D1.

  Based on the travel speed of the traveling machine body 50 based on the detection of the operation position of the shift lever 45 and the feed amount of the feed unit 14 based on the operation position of the fertilizer setting unit 58, the fertilizer determination unit 68 feeds out per unit travel distance. The amount is detected. Based on the distance E1, the fertilizer determining unit 68 detects the total amount of fertilizer consumed from the position K2 to the work end position D1.

  The fertilizer determination unit 68 compares the amount of fertilizer in the hopper 13 at the position K2 with the total amount of fertilizer consumed from the position K2 to the work end position D1. If it is determined that the amount of fertilizer in the hopper 13 at the position K2 is larger than the total amount of fertilizer consumed from the position K2 to the work end position D1, the traveling body 50 reaches the work end position D1 from the position K2. It is determined that the fertilizer in the hopper 13 is not in a shortage state.

  As a result, the work travel is continued without operating the consumption suppression mode. The determination as to whether or not to activate the consumption suppression mode by the fertilizer determination unit 68 is repeatedly performed each time the traveling machine body 50 travels a predetermined distance.

(Operation related to suppression of fertilizer consumption) (Consumption suppression mode is activated)
As shown in FIG. 5, in a state where the current position of the traveling machine body 50 is the position K2 of the work travel line L01, the fertilizer determination unit 68 changes the fertilizer amount of the hopper 13 at the position K2 from the position K2 to the work end position D1. If it is determined that the total amount of fertilizer consumed up to this point is less than the total amount of fertilizer consumed, it is determined that there is a shortage of fertilizer in the hopper 13 before the traveling machine body 50 reaches the work end position D1 from the position K2.

Thus, the consumption suppression mode is activated, and the display device 27 displays that the consumption suppression mode has been activated.
As shown in FIG. 5, by comparing the amount of fertilizer of the hopper 13 at the position K2 and the total amount of fertilizer consumed from the position K2 to the work end position D1, the traveling machine body 50 is moved from the position K2 to the work end position D1. In order to avoid a shortage of fertilizer in the hopper 13, the rotation speed of the feeding motor 54 is automatically operated to the low speed side in the fertilizer application 18.

  As shown in FIG. 5, when the traveling machine body 50 reaches the work end position D1, the driver stops the traveling machine body 50 and replenishes the hopper 13 with the fertilizer placed on the ridge B1. When the replenishment of fertilizer to the hopper 13 is finished, the traveling machine body 50 is caused to travel to the work start position C2, and the next work travel line L02 is started to travel.

(Operation limit setting by manual change part)
As described above, when the consumption suppression mode is activated, if the rotation speed of the feeding motor 54 is operated too low in the fertilizer application apparatus 18, the supply of fertilizer to the field may become too small.

In this case, the manual change unit 57 can arbitrarily set and change the operation limit to the low speed side of the rotational speed of the feeding motor 54 in the state where the consumption suppression mode is activated.
When the above-described operation is performed by the manual changing unit 57, the operation of the traveling machine body 50 is completed by stopping the operation to the low speed side of the rotation speed of the feeding motor 54 in the state where the consumption suppression mode is activated. By the time the positions D1 to D7 are reached, the fertilizer in the hopper 13 may become insufficient.

  In the state as described above, a state where the fertilizer of the hopper 13 is insufficient is displayed on the display device 27. Thereby, the work travel is interrupted, the travel machine body 50 is traveled from the position of the work travel lines L01 to L07 to the shore, the fertilizer placed on the heels B1 to B4 at the coast is replenished to the hopper 13, and the travel machine body The work travel is resumed by traveling 50 to the position of the work travel lines L01 to L07 where the work travel is interrupted from the heel.

(Second embodiment of the invention)
In the above-mentioned (Mode for Carrying Out the Invention) (First Another Mode for Carrying Out the Invention), as described below, the consumption suppression mode may be applied to the fuel in the fuel tank.

As shown in FIGS. 1, 2, and 5, when the traveling machine body 50 is positioned on the work travel lines L01 to L07, if the fuel in the fuel tank decreases, the work travel is interrupted and the travel machine body 50 is moved to the work travel line L01. -Drive from the position of L07 to the shore.
When the fuel tank is refueled, the fuel tanks are replenished to the fuel tank, and when the fuel tank is replenished, the work travel line L01- The work travel is resumed by traveling to the position of L07.

  As shown in FIG. 7, an accelerator setting unit 59 is provided in the traveling machine body 50, and a signal from the accelerator setting unit 59 is input to the control device 23. An accelerator motor 60 for operating an accelerator (not shown) of the engine 31 is provided, and the accelerator motor 60 is operated by the control device 23. The accelerator setting unit 59 is an operation lever type, and the accelerator operation position of the engine 31 can be arbitrarily set by the accelerator motor 60 when the driver operates the accelerator setting unit 59.

  As shown in FIG. 7, a fuel sensor 69 (corresponding to a mounted object detection unit) that detects the amount of fuel in the fuel tank is provided, and a detection value of the fuel sensor 69 is input to the control device 23. A fuel determination unit 70 (corresponding to an on-board determination unit) is provided in the control device 23 as software.

(Operations related to suppression of fuel consumption) (Consumption suppression mode does not operate)
As shown in FIG. 5, it is assumed that the current position of the traveling machine body 50 is the position K2 of the work travel line L01 and the distance E1 from the position K2 to the work end position D1.

  Based on the traveling speed of the traveling vehicle 50 based on the detection of the operating position of the shift lever 45 and the operating position of the accelerator of the engine 31 based on the operating position of the accelerator setting unit 59, the fuel determination unit 70 determines the fuel per unit traveling distance. Consumption is detected. Based on the distance E1, the fuel determination unit 70 detects the total amount of fuel consumed from the position K2 to the work end position D1.

  The fuel determination unit 70 compares the amount of fuel in the fuel tank at the position K2 with the total amount of fuel consumed from the position K2 to the work end position D1. If it is determined that the amount of fuel in the fuel tank at the position K2 is greater than the total amount of fuel consumed from the position K2 to the work end position D1, the travel aircraft body 50 reaches the work end position D1 from the position K2. It is determined that the fuel tank does not run out of fuel.

  As a result, the work travel is continued without operating the consumption suppression mode. The determination of whether or not to operate the consumption suppression mode by the fuel determination unit 70 is repeatedly performed each time the traveling machine body 50 travels a predetermined distance.

(Operation related to suppression of fuel consumption) (Consumption suppression mode is activated)
As shown in FIG. 5, in a state where the current position of the traveling machine body 50 is the position K2 of the work travel line L01, the fuel determination unit 70 causes the amount of fuel in the fuel tank at the position K2 to change from the position K2 to the work end position. If it is determined that the total amount of fuel consumed by D1 is less than the total amount of fuel consumed, it is determined that the fuel in the fuel tank becomes insufficient before the traveling machine body 50 reaches the work end position D1 from the position K2.

Thus, the consumption suppression mode is activated, and the display device 27 displays that the consumption suppression mode has been activated.
As shown in FIG. 5, the traveling body 50 is moved from the position K2 to the work end position D1 by comparing the amount of fuel in the fuel tank at the position K2 with the total amount of fuel consumed from the position K2 to the work end position D1. At least one of the following operations (2-1) and (2-2) is automatically performed so as not to run out of fuel in the fuel tank by the time it reaches.

(2-1) The continuously variable transmission 33 is automatically operated to the low speed side by the transmission motor 53, and fuel consumption is suppressed.
(2-2) The accelerator of the engine 31 is automatically operated to the low speed side by the accelerator motor 60, and fuel consumption is suppressed.

Which of the above-described (2-1) and (2-2) is to be performed when the consumption control mode is activated by the control device 23 by the driver operating the manual changing unit 57. Can be selected in advance.
In this case, any one of the above-mentioned (2-1) and (2-2) can be selected, or both of the above-described (2-1) and (2-2) can be selected. Which of the above-described (2-1) and (2-2) is being performed in the state where the consumption suppression mode is activated is displayed on the display device 27.

As described above, the work travel is continued while the operations (2-1) and (2-2) described above are performed in the state where the consumption suppression mode is activated.
As shown in FIG. 5, when the traveling machine body 50 reaches the work end position D1, the driver stops the traveling machine body 50 and replenishes the fuel tank with the fuel placed on the kite B1. When the fuel supply to the fuel tank is completed, the traveling machine body 50 is caused to travel to the work start position C2, and the next work travel line L02 is started to travel.

(Operation limit setting by manual change part)
As described above, when the consumption restraint mode is activated, if the continuously variable transmission 33 is operated too slowly, the rotation speed of the rotary case 7 becomes too slow in the seedling planting device 5, and the planting arm 8 This may cause problems in planting seedlings.
If the accelerator of the engine 31 is operated too slowly, the output of the engine 31 may be insufficient.

  In this case, the manual changing unit 57 arbitrarily and independently sets the operation limit to the low speed side of the continuously variable transmission 33 and the operation limit to the low speed side of the accelerator of the engine 31 in the state where the consumption suppression mode is activated. And can be changed.

  When the above-described operation is performed by the manual change unit 57, the operation to the low speed side of the continuously variable transmission 33 is stopped at the operation limit in the state in which the consumption suppression mode is activated, or the accelerator 31 of the engine 31 is slow. When the operation to the side is stopped at the operation limit, the fuel tank may run out of fuel before the traveling machine body 50 reaches the work end positions D1 to D7.

  In the state as described above, a state where the fuel in the fuel tank is insufficient is displayed on the display device 27. As a result, the work travel is interrupted, the traveling machine body 50 is caused to travel from the position of the work travel lines L01 to L07 to the shore, the fuel placed on the ridges B1 to B4 at the coast is replenished to the fuel tank, and the traveling machine body The work travel is resumed by traveling 50 to the position of the work travel lines L01 to L07 where the work travel is interrupted from the heel.

(Third Another Embodiment of the Invention)
In the above-mentioned (Mode for Carrying Out the Invention) (First Alternative Embodiment of the Invention) (Second Alternative Embodiment of the Invention), when the consumption suppression mode is activated, the control device 23 performs various automatic operations. Instead of being configured to perform the operation, it may be configured as described below.

When the consumption suppression mode is activated, the display device 27 displays which of the following states (3-1), (3-2), and (3-3).
(3-1) A state in which seedlings are insufficient before the traveling machine body 50 reaches the work end position D1 from the position K2.
(3-2) A state where the fertilizer of the hopper 13 is insufficient before the traveling machine body 50 reaches the work end position D1 from the position K2.
(3-3) A state where the fuel in the fuel tank is insufficient before the traveling machine body 50 reaches the work end position D1 from the position K2.

According to the display on the display device 27, the driver manually performs one or more operations determined as appropriate by the driver among the operations shown in the following (4-1) to (4-6).
(4-1) The planting interval setting unit 46 is operated to operate the inter-equipment transmission 42.
(4-2) The removal amount setting unit 47 is operated to change the removal amount in the vertical direction of the seedlings from the seedling setting table 10 by the planting arm 8.
(4-3) The lateral feed setting unit 49 is operated to change the amount of seedling taken out from the seedling platform 10 by the planting arm 8 in the left-right direction.
(4-4) The fertilizer setting unit 58 is operated to change the rotation speed of the feeding motor 54.
(4-5) The transmission lever 45 is operated to operate the continuously variable transmission 33.
(4-6) The accelerator setting unit 59 is operated to operate the accelerator of the engine 31.

(Fourth embodiment of the invention)
When equipped with a drug supply device (not shown) (corresponding to the supply device) that supplies powdered or liquid medicine (corresponding to the load) to the field, or in place of the seedling planting device 5 (see In the case where a seeding device (corresponding to a supply device) (not shown) for supplying the equivalent) to the field is equipped, the configuration of the consumption suppression mode may be applied to the medicine supply device and the seeding device.

(Fifth embodiment of the invention)
In the above-described consumption control modes (the first embodiment of the invention) to the fourth embodiment of the invention, the traveling machine body 50 reaches the work end positions D1 to D7. Then, after the alarm device (not shown) is activated, the seedling planting device 5 is automatically lifted from the field or the upper lid portion of the hopper 13 is automatically opened. The engine 31 may be configured to automatically stop.

A support mechanism (not shown) may be provided that switches the plurality of preliminary seedling bed 21 to a use posture arranged in a line in the front-rear direction and a non-use posture folded so as to be stacked.
When replenishing loaded items such as seedlings, fertilizers, fuel, etc. from 畦 B1 to B4, equipped with a replenishment stand (not shown) that can be switched between a use posture to receive the load from 畦 B1 to B4 and a non-use posture May be.
When the consumption suppression mode is activated, when the traveling machine body 50 reaches the work end positions D1 to D7, the support mechanism is automatically operated to the use posture, or the replenishment table is automatically operated to the use posture. It may be configured.

(Sixth embodiment of the invention)
In the above-mentioned (Mode for Carrying Out the Invention) (First Alternative Embodiment of the Invention) to (Fifth Alternative Embodiment of the Invention), the work travel line acquisition unit 61 and the turning line acquisition unit 62, automatic travel control The unit 63 and the automatic turning control unit 64 may be eliminated, and only the work end positions D1 to D7 may be acquired by the acquisition unit.

  The present invention is not only a riding type rice transplanter provided with a seedling planting device 5 (corresponding to a working device) at the rear part of the traveling machine body 50 but also a passenger equipped with a seeding device (corresponding to a working device) at the rear part of the traveling machine body 50. Type direct sowing machine, tractor equipped with a rotary tiller (equivalent to a working device) and a chemical spraying device (equivalent to a working device) at the rear of the traveling machine body 50, and a cutting part (equivalent to a working device) at the front of the traveling machine body 50 The present invention can be applied to a work vehicle that travels while working on a farm field, such as a combined combine.

DESCRIPTION OF SYMBOLS 5 Working device, seedling planting device 8 Planting arm 10 Seedling stand 11 Vertical feed mechanism 18 Working device, supply device 30 Positioning unit 31 Engine 33 Traveling transmission device 50 Traveling machine body 57 Manual change unit 61 Acquisition unit 63 Automatic travel control unit 65, 67, 69 Loaded object detection part 66, 68, 70 Loaded object determination part C1-C7 Work start position D1-D7 Work end position L01-L07 Work travel line

Claims (8)

A work device that performs work on the field, a positioning unit that detects a position of the traveling machine body, and an acquisition unit that acquires a work end position located on the heel,
A load detection unit for detecting a remaining amount of a predetermined load consumed as a result of working; and
Based on the detection of the positioning unit and the mounted object detection unit, the mounted object determination unit detects whether the mounted object is in a shortage before the traveling machine body reaches the work end position from the current position. And
A work vehicle in which a consumption suppression mode is activated to suppress consumption of the mounted object when it is determined that the mounted object is in a shortage before the traveling machine body reaches the work end position from the current position. The acquisition unit acquires a work start position and the work end position, and acquires a work travel line connecting the work start position and the work end position,
2. The work vehicle according to claim 1, further comprising: an automatic travel control unit configured to automatically steer the travel machine body so that the travel machine body travels along the work travel line based on the detection of the positioning unit. .   The work vehicle according to claim 1 or 2, wherein in the consumption suppression mode, a driver of the traveling machine body is notified that an operation for suppressing consumption of the mounted object should be performed.   The work vehicle according to claim 1 or 2, wherein an operation for suppressing consumption of the mounted object is automatically performed in the consumption suppression mode. The working device is a seedling planting device for planting seedlings in a field, and the load is a seedling,
An operation for suppressing consumption of the load in the consumption suppression mode is as follows.
An operation of widening the seedling planting interval in the direction of travel of the traveling aircraft by the planting arm;
An operation of reducing the amount of seedling taken out from the seedling platform by the planting arm and reducing the vertical feeding amount of the seedling of the vertical feeding mechanism provided in the seedling platform;
An operation of slowing the lateral feed speed of the seedling platform;
The work vehicle according to claim 4, wherein the operation vehicle is at least one of the operations. The working device is a supply device that supplies at least one of seeds, fertilizers and drugs to the field, and the load is at least one of seeds, fertilizers and drugs,
The work vehicle according to claim 4, wherein the operation for suppressing the consumption of the load in the consumption suppression mode is an operation for reducing a supply amount of the supply device. The load is fuel supplied to the engine of the traveling aircraft;
An operation for suppressing consumption of the load in the consumption suppression mode is as follows.
An operation of operating the traveling transmission of the traveling machine body to a low speed side, an operation of operating an accelerator of the engine to a low speed side,
The work vehicle according to claim 4, which is at least one of the above. In the consumption suppression mode, an operation limit of an operation for suppressing the consumption of the mounted object is set,
The work vehicle as described in any one of Claims 4-7 provided with the manual change part which can change the said operation limit artificially.

Images