JP2022081281A - Work vehicle for agriculture - Google Patents

Abstract

To provide a work vehicle for agriculture capable of automatically and normally turning and traveling even in a filed of a bad condition.SOLUTION: A work vehicle for agriculture capable of automatically traveling includes: a steering device steering left and right travel wheels; an actuator driving the steering device; a differential gear distributing drive power to left and right axles in one or both of the front and rear travel wheels; location information acquisition means for acquiring the location information of the vehicle; and idling detection means for detecting the idling of the travel wheels positioned in the outside of the turn. When the steering device is steered over the prescribed angle, it is determined that the machine body turns, and when the idling of the travel wheels is detected by the idling detection means during the turn of the machine body, the differential rotation of the left and right axles is controlled.SELECTED DRAWING: Figure 9

Description

The present invention relates to an agricultural work vehicle such as a rice transplanter.

Conventionally, agricultural work vehicles such as rice transplanters and combines that automatically repeat straight running and turning in a field have been known.

For example, Patent Document 1 discloses a work vehicle that automatically steers a steering wheel and automatically travels in a field based on position information acquired by a GNSS (Global Navigation Satellite System) receiver.
In the work vehicle described in Patent Document 1, a differential mechanism (differential device) is provided, and when turning, the traveling wheel located on the outer side of the left and right traveling wheels is rotated more. Since the number of rotations of the traveling wheel located on the inner side is suppressed, it is possible to turn smoothly.

JP-A-2018-117564

However, when the work vehicle turns, if the condition of the field is bad and the traveling wheel located on the outside slips, the differential mechanism functions and the rotation speed of the traveling wheel located on the inside is increased. In the restrained state, the driving force is transmitted to the idling outer traveling wheels in an unbalanced manner, which may make traveling difficult.

Further, at this time, there is also a problem that the field becomes rough because the outer traveling wheels continue to idle at the same place.

Therefore, an object of the present invention is to provide an agricultural work vehicle capable of stably turning by automatic traveling even when the condition of the field is bad.

Such an object of the present invention is
A steering device that steers the left and right running wheels,
The actuator that drives the steering device and
A differential that distributes the driving force to the left and right axles on one or both of the front and rear wheels.
Location information acquisition means to acquire vehicle location information,
An agricultural work vehicle that can run automatically and is equipped with a slip detection means that detects the slip of the running wheels located on the outside of the turn.
When the steering device is steered beyond a predetermined angle, it is determined that the aircraft is turning, and it is determined that the aircraft is turning.
This is achieved by an agricultural work vehicle characterized by limiting the differential rotation of the left and right axles when the idling detection means detects the idling of the traveling wheel while the airframe is turning.

According to the present invention, when the steering device of the work vehicle having the position information acquisition means is steered beyond a predetermined angle, the slip detection means detects the slip of the traveling wheel located on the outside of the turn. In this case, since it is configured to limit the differential rotation of the left and right axles on one or both of the front and rear traveling wheels, the driving force is transmitted to the idling traveling wheels among the left and right traveling wheels. It is possible to prevent the situation where the vehicle continues to be idle, transmit an appropriate driving force to the traveling wheels that are not idling, and the work vehicle can make a stable turn by automatic traveling.

In a preferred embodiment of the invention
It is configured to be able to automatically travel on a preset automatic travel route in the field.
When turning on the automatic driving path by automatic driving, the position information of the point where the differential rotation of the left and right axles is restricted is automatically recorded in the recording device.
When automatically traveling in the same field from the next time onward, it is configured to travel on a route in which a part of the automatic traveling route is corrected so as to avoid a point where the differential rotation of the left and right axles is restricted. Has been done.

According to this preferred embodiment of the present invention, when the differential rotation of the left and right axles of one or both of the front and rear wheels is restricted, the position information at that point is automatically recorded in the recording device, and the next time. Subsequent automatic driving is configured to travel on a route that has been corrected to avoid that point, so it is effective to prevent the traveling wheels from slipping again at the same location. Can be done.

In a more preferred embodiment of the invention
It is configured to be able to automatically travel on a preset automatic travel route in the field.
When turning on an automatic driving path by automatic driving, it is configured to allow deviation from the automatic driving path within a predetermined range while the differential rotation of the left and right axles is restricted. There is.

According to this preferred embodiment of the present invention, when the automatic traveling causes the traveling wheels located on the outer side to spin when turning on the automatic traveling path, the differential rotation of the left and right axles is restricted. Since it is configured to allow deviation from the automatic driving path, it is not necessary to turn at a steep angle along the automatic driving path with the differential rotation of the left and right axles restricted, and it is automatic. It is possible to make a large turn away from the traveling path, and therefore, it is possible to prevent a large load from being applied to the traveling wheels and axles, and it is possible to make a stable turn by automatic traveling.

Further, according to this preferred embodiment, it is also possible to prevent the work vehicle from riding on the shore of the field by limiting the range in which the work vehicle deviates from the automatic traveling path.

In a more preferred embodiment of the invention
When the traveling wheels slip when turning on the automatic traveling path due to automatic traveling, and the differential rotation of the left and right axles is restricted, and then the idling of the traveling wheels is eliminated, the left and right axles It is configured to allow the differential rotation of the wheel and return to the automatic travel path on the shortest route.

According to this preferred embodiment of the present invention, when the differential rotation of the left and right axles is restricted and the idling of the traveling wheels is eliminated, the differential rotation of the left and right axles is allowed and the vehicle automatically travels on the shortest route. Since it returns to the route, it is possible to minimize the impact on agricultural work while making a stable turn.

In a more preferred embodiment of the invention
The work vehicle is configured as a seedling transplanting machine having a seedling planting portion at the rear for planting seedlings in the field.
The first inter-strain change mechanism that allows the operator to set the distance between the seedlings to be planted when the seedling transplanter moves forward in a stepwise manner.
A second inter-strain change mechanism capable of changing the inter-strain distance between seedlings in the anteroposterior direction is provided at a position behind the first inter-strain change mechanism and in front of the seedling planting portion.
In the second inter-stock change mechanism, the inter-stock is changed according to the idling rate of the traveling wheel.

According to this preferred embodiment of the present invention, in the second inter-stock changing mechanism provided behind the first inter-stock changing mechanism configured to be configurable by the operator, depending on the idling rate of the traveling wheel. Since the space between the stocks is changed, the space between the stocks can be kept constant in both the place where the running wheels slip frequently and the place where the running wheels slip less.

In a more preferred embodiment of the invention
The second inter-stock change mechanism includes a planetary gear mechanism and an actuator for inter-stock adjustment.
The planetary gear mechanism includes a sun gear that is rotated integrally with an input shaft extending from the first interstock change mechanism, a plurality of planetary gears that revolve around the sun gear, and a plurality of external teeth of the planet gear. An internal gear having meshing internal teeth and an output shaft that transmits the revolving motion of the plurality of planetary gears to the planting transmission shaft that transmits power to the seedling planting portion. Equipped with
The rotation speeds of the internal gear and the output shaft are increased or decreased by the actuator for adjusting between stocks according to the idling rate of the traveling wheel, and the stocks are changed.

According to this preferred embodiment of the present invention, the rotation speeds of the internal gear and the output shaft of the planetary gear mechanism are increased or decreased by an actuator so that the stocks can be changed, so that the second stock change mechanism can be miniaturized. In addition, the range of changes between stocks can be widened.

According to the present invention, it is possible to provide a work vehicle capable of automatically turning and traveling normally even when the condition of the field is bad.

FIG. 1 is a substantially left side view of a seedling transplanting machine according to a preferred embodiment of the present invention. FIG. 2 is a schematic plan view of the seedling transplanting machine shown in FIG. FIG. 3 is a schematic plan view showing a transmission mechanism in the vicinity of the mission case of the seedling transplanter shown in FIG. FIG. 4 is a partially enlarged plan view of the vicinity of the rear wheel of the seedling transplanting machine shown in FIG. FIG. 5 is a block diagram of a control system, a detection system, an input system, a display system, and a drive system of the seedling transplanter shown in FIG. FIG. 6 is a drawing showing a wave barrier on the left side and a side float on the left side. FIG. 7 is an explanatory diagram showing the action of canceling the wave generated from the wave breaker on the left side. FIG. 8 is a schematic plan view showing a route on which the seedling transplanter automatically travels in the field. FIG. 9 is a flowchart showing a control procedure for automatically limiting the differential rotation of the left and right front wheel axles when the vehicle automatically travels on the first path. FIG. 10 is a schematic perspective view showing a transmission mechanism to the seedling planting portion shown in FIG. 1. FIG. 11 is a partial cross-sectional view showing the internal structure of the planted clutch case provided in the mission case. FIG. 12 is a schematic perspective view of the vicinity of the planetary gear mechanism provided in the variable interstock case. FIG. 13 is a schematic perspective view of the front portion of the wave barrier plate on the left side according to another preferred embodiment of the present invention. FIG. 14 is a schematic perspective view showing a state before the cover is attached to the ultrasonic sensor of the seedling transplanter according to the embodiment shown in FIG. FIG. 15 is a schematic perspective view showing a state in which a cover is attached to an ultrasonic sensor. FIG. 16 is a schematic perspective view of the vicinity of the diff lock motor of the seedling transplanting machine 1 according to the embodiment shown in FIG. FIG. 17 shows a control procedure from when the differential rotation of the left and right front wheel axles according to the embodiment shown in FIG. 13 is allowed on the first path until the seedling transplanter returns to the automatic traveling path. It is a flowchart which shows. FIG. 18 is a schematic plan view showing a traveling path from when the differential rotation of the left and right front wheel axles is allowed on the first path to when the seedling transplanter returns to the automatic traveling path. 19 (a) is a schematic perspective view of the vicinity of the left wave barrier according to still another preferred embodiment of the present invention, and FIG. 19 (b) is the left side shown in FIG. 19 (a). It is a schematic horizontal sectional view in the vicinity of the through hole of a wave breaker. FIG. 20 is a schematic perspective view of the vicinity of a sensor mounting arm to which an ultrasonic sensor of a seedling transplanter according to the embodiment shown in FIG. 19 is mounted. FIG. 21 is a drawing showing the left side float of the seedling transplanter according to the embodiment shown in FIG. 22 (a) is a schematic perspective view showing the rear wheel of the conventional seedling transplanter, and FIG. 22 (b) is a schematic perspective view showing the rear wheel of the seedling transplanter according to the embodiment shown in FIG. It is a figure.

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

FIG. 1 is a substantially left side view of the seedling transplanting machine 1 according to a preferred embodiment of the present invention, and FIG. 2 is a schematic plan view of the seedling transplanting machine 1 shown in FIG.

In the present specification, as shown by arrows in FIGS. 1 and 2, the side in the traveling direction of the seedling transplanting machine 1 (an example of an agricultural work vehicle according to the present invention) is defined as the front (F), and is particularly refused. Unless there is, the left side in the traveling direction of the seedling transplanter 1 is referred to as "left" (L in the drawing), and the opposite side is referred to as "right" (R in the drawing).

As shown in FIGS. 1 and 2, the seedling transplanting machine 1 according to the present embodiment includes a traveling vehicle 2 and a seedling planting portion 63 attached to the rear portion of the traveling vehicle 2.

As shown in FIG. 1, the traveling vehicle 2 is attached to a main frame 3 arranged substantially in the center of the traveling vehicle 2 and a rear end portion of the main frame 3, and extends in the width direction of the seedling transplanting machine 1. 6 is provided with a pair of left and right front wheels 8 and a pair of left and right rear wheels 9 (see FIG. 2) as traveling wheels.

As shown in FIGS. 1 and 2, a floor step 60 is provided above the main frame 3, and above the floor step 60, a front cover 47 arranged at the front of the traveling vehicle 2 and a front surface are provided. A control unit 49 arranged behind the cover 47, a controller 87 covered with the front cover 47 to control the seedling transplanting machine 1 (see the left side of the drawing in FIG. 1), and a control seat arranged behind the control unit 49. 48 and are provided. In this embodiment, the seedling transplanting machine 1 is configured to be switchable between a state in which the seedling transplanting machine 1 is automatically driven by the controller 87 and a state in which the seedling transplanting machine 1 is driven by the operator's control (hereinafter referred to as "manual running"). ing.

The control unit 49 includes a steering handle 56 (steering device according to the present invention) that steers a pair of left and right front wheels 8, and an operation unit 54 for operating the seedling transplanting machine 1.

As shown in FIGS. 1 and 2, a fertilizer application device 26 for supplying fertilizer to the field is provided behind the cockpit 48.

As shown in FIG. 1, the fertilizer application device 26 includes a fertilizer hopper 27 for storing fertilizer, a delivery device 34 for feeding out the fertilizer in the fertilizer application hopper 27 downward, and a fertilizer application hose 40 for supplying the delivered fertilizer to the field. I have.

As shown in FIG. 1, an engine 7 is provided below the cockpit 48, and the driving force output from the engine 7 is a belt-type power transmission mechanism 4 provided below the floor step 60 and hydraulic pressure. After being transmitted to the transmission case 30 via the continuously variable transmission 25, the speed is changed by the auxiliary transmission mechanism (not shown in FIG. 1) in the transmission case 30, and the pair of left and right front wheels 8 and the pair of left and right rear wheels 8 are changed. The power for traveling to the wheel 9 and the power for driving the seedling planting portion 63 are separately transmitted.

FIG. 3 is a schematic plan view showing a transmission mechanism in the vicinity of the mission case 30 of the seedling transplanting machine 1 shown in FIG.

The power (torque) for traveling that has been changed by the auxiliary transmission mechanism 20 shown in FIG. 3 is left and right by the differential mechanism 15 (corresponding to the differential device of the present invention) based on the difference in the load applied to the left and right front wheels 8. It is distributed to the front wheel axles 17 and 18, respectively, and is transmitted to the pair of left and right front wheels 8 via the front wheel final case 13 (see FIG. 1). That is, the left and right front wheel axles 17 and 18 are configured to be rotatable at different rotation speeds based on the difference in the load applied to the left and right front wheels 8 (hereinafter, the left and right front wheel axles 17 and 18 or the left and right traveling wheels). When 8 and 9 are rotated at different rotation speeds between the left and right, it is called "differential rotation").

Further, in the present embodiment, the differential mechanism 15 has a differential lock function, and the drive of the differential lock motor 16 shown in FIG. 3 causes a difference in the rotation speeds of the left and right front wheel axles 17 and 18. It is configured to be preventable (hereinafter, limiting the difference in the number of revolutions between the left and right front wheel axles 17 and 18 is called "restricting the differential rotation", and the number of revolutions between the left and right front wheel axles 17 and 18 is limited. The fact that the difference between the two is not limited is called "allowing differential rotation").

Therefore, even though one of the left and right front wheels 8 is idling, the driving force is transmitted only to the idling front wheel 8 among the pair of left and right front wheels 8 to prevent the seedling transplanting machine 1 from becoming difficult to run. can do. In this embodiment, when the differential rotation of the left and right front wheel axles 17 and 18 is restricted, the rotation speeds of the left and right front wheel axles 17 and 18 are substantially the same.

As shown in FIG. 3, a diff lock arm 19 is attached to the diff lock motor 16, and when the diff lock motor 16 is driven, the on / off pin 22 connected to the diff lock arm 19 acts on the diff clutch 23. do. As a result, the differential rotation of the left and right front wheel axles 17 and 18 is limited.

Further, the power transmitted to the pair of left and right rear wheels 9 is taken out from the rear part of the mission case 30, and then the pair of left and right rear wheel transmission shafts 14, the pair of left and right rear wheel gear cases 51, and the axles shown in FIG. It is transmitted to the pair of left and right rear wheels 9 via 82 (see FIG. 1).

As described above, the traveling wheels 8 and 9 are rotated by the power transmitted from the engine 7, and the traveling vehicle 2 moves forward or backward.

Further, a part of the driving force transmitted to the rear wheel gear case 51 is transmitted to the fertilizer application device 26.

On the other hand, the power for driving is transmitted to the planting clutch (not shown in FIGS. 1 to 3) provided at the rear of the traveling vehicle 2, and when the planting clutch is engaged, the seedling planting unit 63 Is transmitted to.

As shown in FIG. 1, the seedling planting portion 63 is connected to the traveling vehicle 2 via the elevating link device 5. The elevating link device 5 includes an upper link arm 85 and a pair of left and right lower link arms 86, and is configured to be able to elevate the seedling planting portion 63.

The front ends of the upper link arm 85 and the lower link arm 86 are attached to the link base frame 10 fixed to the rear frame 6, and the other end is attached to the upper and lower link arms 11 located at the lower part of the seedling planting portion 63. Has been done.

The controller 87 is configured to control an electro-hydraulic valve (not shown in FIGS. 1 to 3), the electro-hydraulic valve is controlled by the controller 87, and the elevating hydraulic cylinder 12 (see FIG. 1) is hydraulically contracted. Then, the upper link arm 85 rotates up and down, and as a result, the seedling planting portion 63 is raised to the non-working position. Further, when the elevating hydraulic cylinder 12 is hydraulically extended, the upper link arm 85 rotates up and down, and as a result, the seedling planting portion 63 is lowered to a working position suitable for planting seedlings in the field. .. When the seedling planting portion 63 is in the non-working position, the lower end portion thereof is located at substantially the same height as the bottom portion of the main frame 3, and when the seedling planting portion 63 is in the working position, the lower end portion thereof is located. Ground.

As shown in FIGS. 1 and 2, the seedling planting section 63 is provided with a table 65 on which a mat-shaped seedling with soil (hereinafter referred to as “seedling mat”) is leaned against, and behind and below the table 65. It is equipped with three planting devices 64.

As shown in FIG. 2, three planting devices 64 are provided side by side in the width direction of the seedling transplanting machine 1, and each planting device 64 includes two pairs of left and right planting tools 69 arranged in the front-rear direction. When the drive shaft 67 shown in FIG. 1 is rotated, the front planting tool 69 and the rear planting tool 69 shown in FIGS. 1 and 2 are alternately rotated around the drive shaft 67. The seedlings located at the lower end of the table 65 are taken out and planted in the field.

As shown in FIGS. 1 and 2, a spare seedling mounting table 74 for accommodating a seedling mat to be replenished in the table 65 is provided at the front portion of the seedling transplanting machine 1 to support the preliminary seedling mounting table 74. It is attached to the traveling vehicle 2 via the frame 77.

FIG. 4 is a partially enlarged plan view of the vicinity of the rear wheel 9 of the seedling transplanting machine 1 shown in FIG.

As shown in FIGS. 1 and 4, a central leveling rotor 31 is provided at the lower part of the left and right pair of rear wheels 9 in the left-right direction, and a pair of left and right rear wheels 9 are behind the left and right pair of rear wheels 9. A leveling rotor 32 is provided.

The central leveling rotor 31 and the pair of left and right leveling rotors 32 are ground leveling devices mainly used in the headland of a field, each of which has a plurality of rotor blades 41, and each rotor blade 41 is a left rear wheel gear case. The field is leveled by being rotated by the driving force transmitted from the driving shaft 37 extending from 51.

As shown in FIG. 4, a center float 38 is provided behind the central leveling rotor 31, and a pair of left and right side floats 39 are provided behind the pair of left and right leveling rotors 32.

As the seedling transplanting machine 1 travels, the center float 38 and the pair of left and right side floats 39 each slide on the field so that the field can be leveled, and the center float 38 and the pair of left and right side floats can be leveled. Seedlings are planted in the fields prepared by 39 using each planting device 64. The front portions of the center float 38 and the pair of left and right side floats 39 are configured to be swingable according to the unevenness of the field.

The center float 38 and the pair of left and right side floats 39 are attached to the planting depth frame 42 extending in the width direction of the seedling transplanting machine 1 at the lower part of the seedling planting portion 63.

FIG. 5 is a block diagram of the control system, the detection system, the input system, the display system and the drive system of the seedling transplanting machine 1 shown in FIG.

As shown in FIG. 5, the control system of the seedling transplanting machine 1 includes a controller 87 that controls the operation of the seedling transplanting machine 1 as a whole.

The controller 87 includes a processing unit 89 having a CPU (Central Processing Unit), a storage unit 93 having a ROM (Read Only Memory) and a RAM (Random Access Memory), and the storage unit 93 controls the seedling transplanting machine 1. Various programs and data are stored. The storage unit 93 is an example of a recording device according to the present invention.

As shown in FIG. 5, the detection system of the seedling transplanter 1 determines the relative angle between the steering sensor 58 that detects the steering angle of the steering handle 56 (an example of the steering device) and the upper link arm 85 with respect to the link base frame 10. The link sensor 90 for detection, the GNSS receiver 130 that functions as a position information acquisition means and receives radio waves from artificial satellites, the front wheel rotation sensor 21 that counts the rotation speeds of the left and right front wheel axles 17 and 18, and the left and right. A pair of a rear wheel rotation sensor 29 that counts the number of rotations of each of the left and right axles 82 connected to the pair of rear wheels 9, a float sensor 33 that detects the vertical position of the front part of the center float 38, and an orientation sensor 80. Between the limit switch 59 that detects the differential lock (limitation of differential rotation) of the front wheel axles 17 and 18, and the stock that detects the operating position of the inter-stock lever and the non-constant speed switching operation tool (not shown in FIGS. 1 to 5). It is equipped with a sensor 97.

The controller 87 is configured to be able to calculate the current height (vertical position) of the seedling planting portion 35 based on the output signal from the link sensor 90.

The float sensor 33 is provided on the front portion of the center float 38, and detects the vertical position of the front portion of the center float 38 when the front portion of the center float 38 is swung according to the unevenness of the field, and is a controller. It is configured to output to 87.

As shown in FIG. 5, the seedling transplanting machine 1 includes an operation unit 54 that functions as an input system, and the operation unit 54 moves forward / backward and forward / backward lever 35 for changing the vehicle speed of the seedling transplanting machine 1 (FIG. 1). It also includes a forward / backward lever sensor 36 that detects the position of (see FIG. 2), and an automatic travel on / off switch 79 that switches automatic travel on / off under the control of the controller 87.

As shown in FIG. 5, the display system of the seedling transplanting machine 1 includes a monitor 61 that displays various information.

As shown in FIG. 5, the drive system of the seedling transplanting machine 1 has an engine 7 provided below the cockpit 48 and an electron that expands and contracts the elevating hydraulic cylinder 12 when the seedling planting portion 35 is moved up and down. The hydraulic valve 88, the HST servo motor 150 that adjusts the opening degree of the tranion shaft (not shown) in the hydraulic stepless transmission 25 to change the forward / backward movement and the vehicle speed of the seedling transplanter 1, and the steering handle 56. A state in which a rotating steering motor 57 (an actuator for driving the steering device according to the present invention) and a differential clutch 23 (see FIG. 3) are turned on and off to allow differential rotation of the left and right front wheel axles 17 and 18. It includes a differential lock motor 16 that switches between a limiting state (diff lock) and an interstock adjustment motor 162 that rotates a planetary gear mechanism (not shown in FIGS. 1 to 4).

The controller 87 shown in FIG. 1 controls the electro-hydraulic valve 88 based on the detection signal from the float sensor 33 to expand and contract the elevating hydraulic cylinder 12 shown in FIG. 1, and the seedling shown in FIG. 1 By raising and lowering the planting section 63, the planting depth of seedlings in the field can be kept constant.

On the other hand, as shown in FIGS. 2 and 4, in the seedling transplanting machine 1 according to the present embodiment, the seedling transplanting machine 1 is outside the width direction of the pair of left and right ground leveling rotors 32 and the pair of left and right side floats 39. A pair of left and right wave barriers 110 are provided.

As the seedling transplanter 1 moves forward, the water waves spreading to the left and right from the pair of ground leveling rotors 32 and the pair of side floats 39 are blocked by the pair of left and right breakwater plates 110. In addition, in FIG. 1, in order to make it easy to see the side float 39 and the like located on the right side of the wave breaker plate 110 on the left side, the wave breaker plate 110 on the left side is transparent so that the back (right side) thereof can be visually recognized. Is illustrated in.

FIG. 6 is a drawing showing the wave breaker 110 on the left side and the side float 39 on the left side, and FIG. 6A is a schematic perspective view of the vicinity of the wave breaker plate 110 on the left side and the side float 39 on the left side. FIG. 6B is a substantially left side view in the vicinity of the wave breaker 110 on the left side and the side float 39 on the left side.

In the present embodiment, as shown in FIGS. 6A and 6B, a protrusion 111 projecting forward is formed in the lower front portion of the wave barrier plate 110 on the left side, and the protrusion 111 on the left side is formed. On the side surface of the waveproof plate 110, six through holes 45 for preventing overflow are formed so as to penetrate the waveproof plate 119 in the left-right direction. The six through holes 45 are formed for the purpose of preventing water on the field from overflowing over the wave barrier 110.

As shown in FIGS. 4, 6 (a) and 6 (b), a wide portion 112 is provided on the outer surface (left surface) of the protrusion 111 in the width direction.

As shown in FIG. 6A, the wide portion 112 is rounded by chamfering one corner of the columnar member 115 (the left portion of the columnar member 115 is chamfered into a substantially conical shape). It is formed by holding and welding to the left surface of the protrusion 111.

The protrusion 111 and the wide portion 112 of the wave breaker 110 on the left side cancel at least a part of the waves generated from the vicinity of the waterline of the wavebreaker 110 on the left side, and the seedlings planted on the left side of the seedling transplanter 1 are It is provided for the purpose of preventing the situation of falling due to the waves. The shape of the wide portion 112 may be configured to form a smooth substantially hemispherical shape, but as in the present embodiment, the wide portion 112 is formed by chamfering the columnar member 115. It can be manufactured at low cost.

FIG. 7 is an explanatory diagram showing the action of canceling the wave generated from the wave breaker 110 on the left side.

FIG. 7 shows the left side surface of the front portion of the wave barrier plate 110 on the left side.

The protrusion 111 is located below the water surface line (waterline, shown by a two-dot chain line in FIG. 6A and shown by a broken line in FIG. 7) held on the field 200 (position submerged in water). ).

Here, as shown in FIG. 7, the wave 117 (shown by the alternate long and short dash line in FIG. 7) generated by the protrusion 111 of the wave barrier 110 on the left side as the seedling transplanting machine 1 advances is on the left side. It has a substantially opposite phase relationship with the wave 116 (shown by the alternate long and short dash line in FIG. 7) generated by the portion near the waterline of the breakwater plate 110 (the portion shown by the diagonal line in FIG. 7). In other words, the projecting portion 111 projects forward so as to form a wave having substantially the opposite phase to the wave 116 as the seedling transplanting machine 1 advances.

As a result, as the seedling transplanter 1 moves forward, the wave 116 generated by the portion near the waterline of the wave breaker 110 on the left side (the portion shown by the diagonal line in FIG. 7) and the wave breaker 110 on the left side The waves 117 generated by the protrusions 111 cancel each other out, as shown in FIG.

Therefore, when the seedling transplanting machine 1 moves forward, the wave of water on the field is suppressed from the wave-proof plate 110 on the left side to the left side of the seedling transplanting machine 1, and the seedling transplanting machine 1 is planted on the left side. It is possible to prevent the seedlings from being overthrown by the waves.

Further, in the present embodiment, a wide portion 112 is provided on the left side of the protruding portion 111 formed on the left wave barrier plate 110, and the wide portion 112 is abbreviated as a wave 117 generated from the protruding portion 111. It is a wave of the same phase and is located at a front-rear position where a wave having a substantially opposite phase to the wave 116 generated from a portion near the waterline of the breakwater plate 110 on the left side can be formed.

With this configuration, the amount of waves that are substantially in phase with the waves 116 generated by the vicinity of the waterline of the left breakwater plate 110 is increased, and the wave canceling effect on the left side of the left breakthrough plate 110 is increased. Can be enhanced.

Further, in the present embodiment, the wave breaker 110 on the left side is a parallel link 46 provided with a first arm 43 and a second arm 44, as shown in FIGS. 6 (a) and 6 (b). It is mounted so that it can swing.

The first arm 43 has a planting portion frame (not shown) fixed to the elevating link device 5 (see FIG. 1), and the second arm 44 has a planting depth to which the side float 39 is attached. Each of the frames 42 is swingably attached.

In this way, since the second arm 44 is attached to the planting depth frame 42 of the seedling planting portion 63, the height position of the seedling planting portion 63 is changed based on the detection signal of the float sensor 33. If so, the height position of the left wave breaker 110 is subsequently changed, and thus the draft position of the left side breaker 110 is maintained.

That is, even if the height position of the seedling planting portion 63 is changed when the seedlings are being planted, the protruding portion 111 and the wide portion 112 of the wave barrier plate 110 on the left side are the fields 200. It is held below the surface of the water stored in the water. Therefore, as the seedling transplanter 1 advances, a wave substantially opposite to the wave 116 generated from the vicinity of the waterline of the wave barrier 110 on the left side (the portion shown by the diagonal line in FIG. 7) is projected. It can continue to be formed by the 111 and the wide portion 112. At this time, as shown in FIG. 6B, the height positions of the wave barrier 110 on the left side and the side float 39 on the left side are substantially aligned.

On the other hand, in the present embodiment, as shown in FIG. 4, a wide portion (a portion extending to the right from the protruding portion 111) is not provided on the right side surface of the protruding portion 111 of the left wave barrier plate 110. ..

Therefore, as the seedling transplanter 1 moves forward, on the right side of the wave breaker 110 on the left side, a wave substantially opposite to the wave 116 generated from the vicinity of the waterline of the breaker plate 110 on the left side is on the left side. It is not formed as much as the case where the wide portion is also provided on the right side of the wave breaker 110.

As a result, a slight wave of water is formed from the front to the substantially rear on the right side of the breakwater plate 110 on the left side (inside in the width direction of the seedling transplanting machine 1). It is possible to further suppress the spread of water waves from the inside to the outside (left side) in the width direction of the seedling transplanting machine 1 as compared with the case where the seedling transplanting machine 1 is provided.

Although the left side waveproof plate 110 has been described in detail above, the right side waveproof plate 110 shown in FIG. 4 is also configured in the same manner, and the protrusion formed in the front lower portion of the right side waveproof plate 110. A wide portion 112 is provided only on the right side surface of the portion 111.

Therefore, as the seedling transplanting machine 1 travels, it is possible to effectively suppress the spread of waves to the right side of the breakwater plate 110 on the right side.

On the other hand, the seedling transplanting machine 1 according to the present embodiment can plant seedlings in the field while automatically traveling in the field as follows, based on the control of the controller 87.

FIG. 8 is a schematic plan view showing a route through which the seedling transplanting machine 1 automatically travels in the field.

As shown in FIG. 8, the field 200 in which the seedling transplanting machine 1 according to the present embodiment automatically travels has a substantially rectangular shape in a plan view, and has four sides 201 to 204 extending in the north-south direction or the east-west direction, and each side. It is a paddy field having four peripheral areas 211 to 214 extending along 201 to 204 and a central area 210 surrounded by four peripheral areas 211 to 214.

In order to plant seedlings in the field while the seedling transplanting machine 1 automatically runs in the field 200, first, the controller 87 obtains position information regarding the four corners of the field 200 in which the seedling transplanting machine automatically runs, and the reference when going straight. Acquires the position information of the reference line.

Specifically, in the present embodiment, the seedling transplanting machine 1 is set along the three sides 201 to 203 in the field 200 forming a substantially rectangular shape with the automatic traveling on / off switch 79 turned on by the operator. After manually traveling (teaching) the peripheral regions 211 to 213 in order, the operator turns off the automatic traveling on / off switch 79.

Next, the controller 87 calculates an automatic traveling route based on the position information acquired by the GNSS receiver 130 when traveling on three sides in the field 200, and stores the data in the storage unit 93.

In the present embodiment, the data of the automatic traveling route includes straight running in the central region 210 (shown by the alternate long and short dash line in FIG. 8) and turning in the peripheral regions 212 and 214 (shown by the alternate long and short dash line in FIG. 8). Data of a route to be repeated (hereinafter referred to as "first route") and a route traveling through the peripheral regions 211 to 214 in order after traveling the first route (shown by a gray arrow in FIG. 8 below. , "Second route") and the first planting start position 205 (shown by a broken line in FIG. 8) to start planting seedlings when traveling straight from south to north on the first route. ) And the data of the second planting start position 206 (shown by the broken line in FIG. 8) where the planting of seedlings is started when traveling straight from north to south.

After the data of the automatic traveling route is stored in the storage unit 93, the seedling transplanting machine 1 manually travels to the position 207 where the seedling planting is started when traveling straight through the first row of the first route.

In this way, when the position 207 where the planting of seedlings is started is reached, the automatic traveling on / off switch 79 is turned on by the operator, and the seedling transplanting machine 1 automatically travels on the first route and seedlings in the central region 210. Plant.

Specifically, the seedling transplanting machine 1 is based on the detection signal output from the direction sensor 80 and the steering sensor 58, the current position information of the seedling transplanting machine 1 output from the GNSS receiver, and the automatic traveling route. By driving the HST servomotor 150 and the steering motor 57, as shown in FIG. 8, the seedlings are planted and the peripheral region is planted while traveling straight north on the "first row" located at the western end of the central region 210. When it reaches 212, it turns and runs straight south on the adjacent row (“second row”), planting seedlings, and when it reaches the peripheral area 214, it turns and turns on the adjacent row (“3”). Seedlings are planted while traveling straight north in the "row"), and in the same manner, the seedling transplanter 1 automatically travels to the "nth row" located at the eastern end of the central region 210. Seedlings are planted in the central area 210.

Finally, the seedling transplanting machine 1 plants seedlings in the peripheral regions 211 to 214 while automatically traveling on the second route in order, and ends the automatic traveling.

On the other hand, in the present embodiment, when turning on the first route by automatic driving (shown by a two-dot chain line in FIG. 8), the front and rear traveling wheels 8 and 9 slip (shown by the mud and ruts of the field). In the case of slipping), the seedling transplanting machine 1 can detect the slipping and automatically return to the turning running as follows.

FIG. 9 is a flowchart showing a control procedure for automatically limiting the differential rotation of the left and right front wheel axles 17 and 18 when the vehicle automatically travels on the first path.

As shown in FIG. 9, the controller 87 first acquires the detected value of the steering angle of the steering handle 56 from the steering sensor 58 (step S1).

Next, the controller 87 determines whether or not the seedling transplanting machine 1 is turning by comparing the steering angle of the steering handle 56 detected by the steering sensor 58 with a predetermined angle (step S2).

Specifically, when the steering angle of the steering handle 56 exceeds a predetermined angle, it is determined that the seedling transplanting machine 1 is turning, and when the steering angle does not exceed the predetermined angle, the seedling transplanting machine 1 is determined to be turning. It is determined that the machine 1 is not turning (running straight).

As a result of the determination, when it is determined that the seedling transplanting machine 1 is not turning, the controller 87 determines that the value detected by the controller 87 from the steering sensor 58 until the steering angle of the steering handle 56 exceeds a predetermined angle. Acquisition and judgment are repeated.

On the other hand, when it is determined that the seedling transplanting machine 1 is turning as a result of the determination, the controller 87 acquires the position information of the seedling transplanting machine 1 from the GNSS receiver 130 and the rear wheel rotation sensor 29. From the above, a detection signal regarding the rotation speed of the axle 82 (see FIG. 1) of the rear wheel 9 located on the outer side during turning is acquired (step S3).

Next, the controller 87 determines whether or not the traveling wheels 8 and 9 are idling based on the position information acquired by the GNSS receiver 130 and the detection signal output from the rear wheel rotation sensor 29 (step S4). ..

Specifically, the moving distance of the seedling transplanting machine 1 estimated from the rotation speed of the axle 82 (see FIG. 1) of the rear wheel 9 on the outer turning side detected by the rear wheel rotation sensor 29 is acquired by the GNSS receiver 130. If it does not match the actual moving distance of the seedling transplanting machine 1 calculated from the position information, it is determined that the traveling wheel 8.9 is idling, and if it matches, the traveling wheel 8.9 is idling. It is determined that it has not been done. That is, the GNSS receiver 130 and the rear wheel rotation sensor are examples of the slip detection means of the present invention.

In this embodiment, when the seedling transplanting machine 1 is turned, it is directly outward when the seedling transplanting machine 1 is turned, based on the axle 82 of the rear wheel 9 located on the outside and the position information of the seedling transplanting machine 1. It is detected that the positioned rear wheel 9 is slipping. However, since the seedling transplanting machine 1 has not been able to travel a distance corresponding to the rotation of the rear wheels 9, when the seedling transplanting machine 1 is turned, the other traveling wheels 8 and 9 also slip in the same manner. It is presumed that the driving force is not sufficiently transmitted by the differential mechanism 15.

In this way, as a result of determining whether or not the traveling wheel 8.9 is idling, if it is determined that the traveling wheel 8.9 is idling, the controller 87 drives the diff lock motor 16 (see FIG. 3). The differential rotation of the left and right front wheel axles 17 and 18 is restricted, and the position information at this point is stored (recorded) in the storage unit 93 (step S5).

As a result of the limited differential rotation of the left and right front wheel axles 17 and 18, the driving force for running is not transmitted to the idling left and right front wheels 8 in a biased manner, and is not transmitted to the idling front wheels 8. The seedling transplanting machine 1 can steadily return to the turning running because it is sufficiently transmitted. The drive of the diff lock motor 16 is stopped when the values of the rotation speeds of the left and right front wheel axles 17 and 18 output from the front wheel rotation sensor 21 are equal.

Here, when the seedling transplanting machine 1 is turned, the traveling wheels 8 and 9 slip and the seedlings are transplanted within a predetermined range while the differential rotation of the left and right front wheel axles 17 and 18 is restricted. It is configured to allow the machine 1 to deviate from the automatic travel path.

With this configuration, the seedling transplanter 1 does not need to turn at a steep angle along the automatic traveling path in a state where the differential rotation of the left and right front wheel axles 17 and 18 is restricted, and the seedling transplanting machine 1 automatically travels. It is possible to make a big turn off the route.

Therefore, it is possible to prevent a large load from being applied to the pair of left and right front wheels 8 and the pair of left and right front wheel axles 17 and 18.

Further, since the range in which the seedling transplanting machine 1 deviates from the automatic traveling path is limited to a predetermined range, it is possible to prevent the seedling transplanting machine 1 from turning excessively when turning and riding on the shore of the field. can do.

A limit switch 59 is provided in the vicinity of the diff lock arm 19 (not shown in FIG. 3), and when the diff lock motor 16 is driven, a part of the diff lock arm 19 comes into contact with the limit switch 59. , The operation of the diff lock (limitation of differential rotation of front wheel axles 17 and 18) is detected. At this time, the monitor 61 displays that the diff lock is operating.

In this way, after the differential rotation of the left and right front wheel axles 17 and 18 is restricted, the controller 87 acquires the position information of the seedling transplanting machine 1 from the GNSS receiver 130, and is outward from the rear wheel rotation sensor 29 when turning. The detection signal about the rotation speed of the axle 82 (see FIG. 1) of the positioned rear wheel 9 is acquired (step S6).

Next, the controller 87 determines whether or not the idling of the traveling wheels 9 and 10 has been eliminated from the acquired position information of the seedling transplanting machine 1 and the rotation speed of the axle 82 of the rear wheels 9 (step S7).

Specifically, the moving distance of the seedling transplanting machine 1 estimated from the rotation speed of the axle 82 of the rear wheel 9 on the outer turning side detected by the rear wheel rotation sensor 29 is calculated from the position information acquired by the GNSS receiver 130. If it does not match the actual moving distance of the seedling transplanting machine 1, it is determined that the idling of the traveling wheel 8.9 has not been eliminated.

On the other hand, if the moving distance of the seedling transplanting machine 1 estimated from the rotation speed of the axle 82 of the rear wheel 9 on the outer side of the turn matches the actual moving distance of the seedling transplanting machine 1 calculated from the position information, the vehicle travels. It is determined that the idling of the wheel 8.9 has been eliminated.

As a result of the determination, when the idling of the traveling wheel 8.9 is eliminated, it is presumed that the wheel has already been removed from the muddy field, ruts, etc., so that the controller 87 drives the diff lock motor 16. The differential rotation of the left and right front wheel axles 17 and 18 is allowed, and the normal turning operation is restored (step S8).

Here, it is presumed that the seedling transplanting machine 1 is off the automatic traveling path due to the influence that the differential rotations of the left and right front wheel axles 17 and 18 are restricted. When the differential locks of the front wheel axles 17 and 18 are released, the automatic driving route is changed to the shortest path from the current location to the first planting start position 205 or the second planting start position 206, whichever is closer. It is configured to drive automatically on the route.

With such a configuration, it is possible to prevent a situation in which seedlings are not partially planted in the central region 210 of the field 200.

Further, by configuring to return to the first planting start position 205 or the second planting start position 206, compared to the case of returning to a place on the automatic traveling route and close to the diff lock point. Therefore, it is possible to prevent the traveling wheels 8 and 9 from slipping again due to ruts or mud.

On the other hand, as a result of determining whether or not the idling of the traveling wheels 9 and 10 is eliminated, if the idling of the traveling wheels 8.9 is not eliminated, the seedling transplanting machine 1 escapes from the muddy or rut of the field. Since it is presumed that this has not been possible, until it is determined that the idling of the traveling wheel 8.9 has been eliminated, the position information and the detection value of the rotation speed of the axle 82 located outside when turning are obtained. The determination as to whether or not the idling has been resolved is repeated.

As described above, the seedling transplanting machine 1 according to the present embodiment uses the rear wheel rotation sensor 29 and the GNSS receiver 130 when the front and rear traveling wheels 8 and 9 are idling due to mud or ruts in the field. Based on this, by detecting this and limiting the differential rotation of the left and right front wheel axles 17 and 18, it is possible to automatically return to turning.

Further, in the seedling transplanting machine 1 according to the present embodiment, when the field 200 is automatically traveled from the next time onward, the field 200 is automatically calculated based on the automatic traveling route calculated for the first time and stored in the storage unit 93. Since the seedlings can be planted while traveling, it is not necessary to manually travel the field 200 and recalculate the automatic traveling route.

Here, in the field 200, if the position information of the point where the differential rotation of the left and right front wheel axles 17 and 18 is restricted is recorded when the field 200 is automatically run before, the field 200 is automatically run from the next time onward. At the time of traveling, from 5 m before the recorded position, travel on a new route shifted (corrected) by 10 cm in the width direction of the seedling transplanter 1 from the automatic traveling route, and pass the recorded position by 5 m. It is configured to return to the automatic driving route.

Therefore, it is possible to prevent the traveling wheel 8.9 from idling again due to the muddy or rut that the traveling wheel 8.9 slipped last time.

On the other hand, FIG. 10 is a schematic perspective view showing a transmission mechanism to the seedling planting portion 63 shown in FIG. 1.

Further, FIG. 11 is a partial cross-sectional view showing the internal structure of the planted clutch case provided in the mission case 30.

The power for driving the seedling planting section 63 is usually transmitted to the drive shaft 67 (see FIG. 1) of the seedling planting section 63 through the planting transmission shaft 95 shown in FIGS. 1 and 10, and is planted. The tool 69 is rotated.

Here, when the seedling transplanting machine 1 is traveling straight and the seedlings are planted in the field using the planting tool 69 (see FIG. 1), the drive shaft 67 (see FIG. 1) is usually driven to rotate the planting tool 69. There is a correlation between the rotation speed of the traveling vehicle 2 and the vehicle speed of the traveling vehicle 2 (rotation of the traveling wheels 8 and 9).

Specifically, since it is necessary to keep the distance between seedlings in the traveling direction of the seedling transplanting machine 1 (hereinafter referred to as "between stocks") constant, the faster the traveling wheels 8 and 9 are rotated, the more the drive shaft 67 is. Is rotated faster, and the planting speed of the planting tool 69 is also increased.

However, in an actual field, when the running wheels 8 and 9 slip (slip) due to the muddyness and ruts of the field 200, the space between the stocks is clogged, or the surface of the field 200 is compacted, the running wheels 8 , 9 slips less and the space between stocks may widen.

Normally, the seedling transplanter is provided with the inter-strain lever 180 shown in FIGS. 1 and 11 and the non-constant speed switching operation tool 190 shown in FIG. 11, and the operator uses these to perform a mission. The internal structure (gears) in the planted clutch case 181 provided in the case 30 (see FIG. 11) can be operated to change the rotation speed of the drive shaft 67 to change the seedling stocks (see FIG. 11). Equivalent to the first inter-stock change mechanism).

However, while the seedling transplanting machine 1 is running, it is difficult to adjust the inter-strains by operating the inter-strain lever 180 or the non-uniform speed switching operation tool 190 each time according to the state of each place in the field 200. Met.

In light of such a situation, in the seedling transplanting machine 1 according to the present embodiment, the variable stock case 160 is connected to the output shaft 73 of the mission case 30, and the rotary drive is output from the planting clutch case 181. After the force is automatically adjusted in the variable interstitial case 160 shown in FIG. 10 based on the slip ratio of the traveling wheels 8 and 9, the drive shaft 67 is passed through the planted transmission shaft 95. It is configured to be transmitted to.

The idling speed of the traveling wheels 8 and 9 is the actual moving distance of the seedling transplanting machine 1 calculated from the position information acquired by the GNSS receiver 130, and the rear wheels on the outer turning side detected by the rear wheel rotation sensor 29. It is calculated by subtracting a value calculated by dividing by the moving distance of the seedling transplanting machine 1 estimated from the rotation speed of the axle 82 (see FIG. 1) of 9 from 1.

As shown in FIG. 11, the inter-stock shift lever 180 shown in FIG. 1 is attached to the front portion of a rod-shaped inter-stock shift shifter 182 extending in the front-rear direction, and when the inter-stock shift lever 180 is operated, the inter-stock shift shifter The rear portion of the 182 is configured to be moved in the front-rear direction in the cylindrical gap 183 formed in the planting clutch case 181.

As shown in FIG. 11, the interstock speed change shifter 182 is formed with four grooves 184 to 187 arranged in the front-rear direction, and the ball 189 is formed by the pressing force of the spring 188 provided in the planting clutch case 181. However, it is constantly pressed against the inter-stock speed change shifter 182.

When the inter-stock shift lever 180 is operated and the inter-stock shift shifter 182 is moved in the front-rear direction, the ball 189 is fitted into one of the grooves 184 to 187, and the position of the inter-stock shift shifter 182 is temporarily fixed.

At this time, when the interstock speed changer 182 is pushed in the front-rear direction by a force exceeding the pushing pressure of the spring 188, the fitted ball 189 is disengaged from the groove 184 to 187 and is fitted into another groove 184 to 187 again. ..

In the present embodiment, the variable interstock case 160 shown in FIG. 10 is passed through the planting clutch 171 depending on the position in the front-rear direction of the interstock speed change shifter 182 (which groove 184 to 187 the ball 189 is fitted into). The speed of the rotational driving force transmitted to the vehicle is configured to be adjustable in four stages as follows. That is, by operating the inter-stock lever 180 and the non-constant speed switching operation tool 190, the inter-stock can be set in four stages, and the higher the speed of the rotational driving force transmitted to the variable inter-stock case 160 is set, the higher the speed is set. Since the rotation speed of the drive shaft 67 with respect to the vehicle speed is also increased, the space between the stocks is narrowed.

When the maximum speed is set among the four stages, the operator first operates the non-constant speed switching operation tool 190. The non-constant speed switching shifter 191 is moved to the position (b) shown in FIG. 11, and the clutch claw 170 of the gear 198 on the output shaft 196 and the clutch claw 169 of the non-uniform speed switching clutch 199 are engaged.

Further, the inter-stock lever 180 is operated by the operator, and the ball 189 is fitted into the first groove 184 shown in FIG. 11 formed on the inter-stock shift shifter 182.

As a result, the gear 194 is integrally formed with the gear position control plate 195 fixed to the interstock speed change shifter 182 and the gear 192, and the rotational power is input to the planted clutch case 181 with respect to the input shaft 193. The gear 194 fitted (free-fitted) with play meshes with the gear 197 fixed to the output shaft 196, and the gear 198, the non-constant speed switching clutch 199 and the output shaft 196 and the planting clutch 171 are engaged. The rotational driving force is output to the variable interstitial case 160 at the highest speed.

When the speed is set to the second fastest of the four stages, the operator operates the non-constant speed switching operation tool 190, and the non-constant speed switching shifter 191 is located at the position (b) shown in FIG. The inter-stock lever 180 is operated in the state of being moved to, and the ball 189 is fitted into the groove 185 of the inter-stock speed change shifter 182.

As a result, the gear 192 on the input shaft 193 and the gear 179 fixed to the output shaft 196 mesh with each other, and at the second fastest speed via the non-constant speed switching clutch 199, the output shaft 196 and the planting clutch 171. The rotational driving force is output to the variable interstock case 160.

When the speed is set to the third fastest of the four stages, the operator operates the non-constant speed switching operation tool 190, and the non-constant speed switching shifter 191 is located at the position (b) shown in FIG. The inter-stock lever 180 is operated in the state of being moved to, and the ball 189 is fitted into the groove 186 of the inter-stock speed change shifter 182.

As a result, the clutch claw 178 of the gear 192 and the clutch claw 176 of the gear 177 on the input shaft 193 mesh with each other, the gear 175 on the output shaft 196 is rotated, and the gear 179, the gear 196, the gear 198, and the non-constant speed switching clutch are rotated. A rotational driving force is output to the variable interstock case 160 at the third fastest speed via the 199, output shaft 196 and planting clutch 171.

When the lowest speed is set among the four stages, the operator operates the non-constant speed switching operation tool 190, and the non-constant speed switching shifter 191 is moved to the position (a) shown in FIG. In this state, the inter-stock lever 180 is operated, and the ball 189 is fitted into the groove 187 of the inter-stock speed change shifter 182.

As a result, the gear 177 on the input shaft 193 is transmitted to the gear 175 on the output shaft 196, and the gear 174 on the input shaft 193 and the gear 198 on the output shaft 196 are meshed with each other at all times. From the gear 173 on the input shaft and the gear 172 on the output shaft and the non-constant speed switching clutch 199, the rotational driving force is output to the variable interstock case 160 at the lowest speed via the output shaft 196 and the planting clutch 171. Will be done.

The rotational driving force output to the variable stock case 160 as described above is increased / decreased or temporarily stopped in the variable stock case 160 and its vicinity as follows.

FIG. 12 is a schematic perspective view of the vicinity of the planetary gear mechanism provided in the variable interstock case 160.

In this embodiment, the planetary gear mechanism 161 is provided inside the variable interstock case 160 (see FIG. 10).

The planetary gear mechanism 161 and the inter-stock adjustment motor 162 in the variable inter-stock case 160 correspond to the second inter-stock change mechanism.

As shown in FIG. 12, the planetary gear mechanism 161 includes an internal gear 164 having teeth 158 or 157 on the outside and inside, a sun gear 163 and two planetary gears 165 provided inside the internal gear 164, and two. A planetary carrier 168 having two shafts 167 inserted into each of the two planetary gears 165 and an output shaft 155 attached to the rear of the planetary carrier 168 (output shaft to the planting transmission shaft 95, also see FIG. 10). ) Is provided.

The two planetary gears 165 are meshed with the sun gear 163 and the internal gear 164.

On the other hand, the input shaft 166 extending from the planting clutch case 181 (see FIG. 11) is inserted inside the sun gear 163 of the planetary gear mechanism 161.

Therefore, when the planting clutch 171 is engaged and the input shaft 166 is rotated, the sun gear 163 is rotated integrally with the input shaft 166, and the two planetary gears 165 also rotate around the sun gear 163 of the sun gear 163. It is rotated in the direction opposite to the direction of rotation.

As a result, the internal gear 164, the planet carrier 168, and the output shaft 155 are rotated, and the rotational driving force is transmitted to the planting transmission shaft 95 (see FIG. 10).

Here, as shown in FIG. 12, a gear 159 that can be rotated by the drive of the interstock adjustment motor 162 configured as a variable speed motor is meshed with the outside of the internal gear 164.
Then, the controller 87 changes the voltage applied to the inter-stock adjustment motor 162 at a speed corresponding to the idling rate of the traveling wheels 8 and 9 to rotate the gear 159, and switches the actual inter-stock lever 180 and the non-constant speed between the stocks. It is configured to keep the length set by the operation of the operation tool 190 (based on the output signal from the inter-stock sensor 97 that detects the operation position of the inter-stock lever 180 and the non-constant speed switching operation tool 190).

Specifically, when the idling rate of the traveling wheels 8 and 9 is higher than a predetermined value, it is estimated that the inter-stock spacing is narrower than the set value. Therefore, the gear 159 is driven by the inter-stock adjusting motor 162. , It is rotated at a low speed according to the idling rate.

At this time, since the planetary gear mechanism 161 is rotated at a low speed (a speed lower than that rotated by the rotational power from the input shaft 166), the drive shaft 67 (see FIG. 1) is rotated at a low speed, and the space between the stocks is increased. It is adjusted to the set length.

On the other hand, when the idling rate of the traveling wheels 8 and 9 is lower than a predetermined value, it is estimated that the space between the stocks is wider than the set value. It is rotated at a high speed according to.

At this time, since the planetary gear mechanism 161 is rotated at a high speed (higher speed than that rotated by the rotational power from the input shaft 166), the drive shaft 67 (see FIG. 1) is rotated at a high speed, and the space between the stocks is increased. It is adjusted to the set length.

Further, when the idling rate of the traveling wheels 8 and 9 is 100% (the seedling transplanting machine 1 is not moving), the interstock adjustment motor 162 is driven in order to prevent the seedlings from being continuously planted in the same place. Is stopped.

Further, in the present embodiment, the gear 159 is provided with a bidirectional ratchet mechanism, and when the drive of the interstock adjustment motor 162 is stopped, the rotation of the planetary gear mechanism 161 is stopped, so that the drive shaft 67 The rotation of is also stopped.

In this way, by changing the voltage applied to the inter-strain adjustment motor 162, it is possible to smoothly adjust the inter-strain spacing between the seedlings actually planted in the front-rear direction. The inter-stock adjustment motor 162 is located in the motor case 156 (see FIG. 10) shown in FIG.

In the present embodiment, a protrusion 111 that protrudes forward is provided in the front lower portion of the wave barrier 110 provided on the left and right sides of the seedling transplanting machine 1, and is a side surface of the protruding portion 111, which is a side surface of the seedling transplanting machine. A wide portion 112 extending outward from the protruding portion 111 is provided on the outer surface of 1 in the width direction. The protruding portion 111 and the wide portion 112 are located below the waterlines of the pair of left and right wave barriers 110, and as the seedling transplanting machine 1 advances, the protrusions 111 and the wide portions 112 are located near the waterlines of the left and right wave barriers 110. It is configured to be able to form a wave having a phase substantially opposite to that of the generated wave 116.

Therefore, the wave 116 generated from the near portion of the waterline (see the diagonal line in FIG. 7), which is the front portion of the breakwater plate 110, interferes with and cancels the wave having substantially the opposite phase generated by the projecting portion 111 and the wide portion 112. Therefore, it is possible to suppress the spread of water waves from the left and right wave barriers 110 to the left and right of the seedling transplanting machine 1 and prevent the seedlings planted on the left and right of the seedling transplanting machine 1 from collapsing. can.

Further, according to the present embodiment, as shown in FIG. 4, a wide portion 112 is provided on the inner surface (the inner surface in the width direction of the seedling transplanting machine 1) of the protruding portions 111 of the left and right wave barrier plates 110. Since it is not provided and a slight wave of water can be formed on the right side of the wave breaker 110 (inside in the width direction of the seedling transplanter 1) as the seedling transplanter 1 advances, the wave breaker can be formed. It is possible to further suppress the spread of waves on the right side of the plate 110.

Further, in the present embodiment, since the left and right wave barriers 110 are attached to the planting depth frame 42 via the second arm 44 shown in FIG. 6, depending on the unevenness of the field. Based on the detection signal of the float sensor 33, it is configured to move up and down following the seedling planting portion 63. Therefore, due to the unevenness of the field, the protruding portions 111 and the wide portions 112 provided on the left and right wave barrier plates 110 float from the water stored in the field or excessively sink in the mud of the field 200. That is, the draft positions of the left and right wave barriers 110 (see the two-dot chain line in FIG. 6B) can be maintained, and the wave canceling effect can be sustained.

Further, in the present embodiment, the steering handle 56 of the seedling transplanter 1 having the GNSS receiver 130 is steered beyond a predetermined angle, and the GNSS receiver 130 and the rear wheel rotation sensor 29 are used. When the idling of the traveling wheels 9 and 10 is detected, the differential rotation of the left and right front wheel axles 17 and 18 is restricted.

Therefore, sufficient rotational power can be transmitted to the front wheels 8 that are not idling, and in the automatic traveling by the controller 87, the muddy and ruts of the field can be automatically removed and the vehicle can turn steadily.

Further, according to the present embodiment, when the differential rotation of the left and right front wheel axles 17 and 18 is restricted, the position information at that point is automatically recorded in the storage unit 93, and the vehicle automatically travels from the next time onward. In some cases, it is configured to travel on a route that has been corrected (shifted) to avoid that point, so it effectively prevents the traveling wheels 8 and 9 from slipping again at the same location. can do.

Further, in the present embodiment, while the traveling wheels 8 and 9 slip and the differential rotation of the left and right front wheel axles 17 and 18 is restricted when turning on the automatic traveling path by the automatic traveling. Within a predetermined range, the seedling transplanting machine 1 is configured to allow deviation from the automatic traveling path.

Therefore, the seedling transplanting machine 1 does not need to turn at a steep angle along the automatic traveling path with the differential rotation of the left and right front wheel axles 17 and 18 restricted, and makes a large turn away from the automatic traveling path. Therefore, it is possible to prevent a large load from being applied to the pair of left and right front wheels 8 and the pair of left and right front wheel axles 17 and 18, and to steadily turn by automatic traveling.

Further, according to the present embodiment, when the differential rotation of the left and right front wheel axles 17 and 18 is restricted, the seedling transplanting machine 1 limits the range deviating from the automatic traveling path. Can be prevented from riding on the shore of the field 200.

Further, according to the present embodiment, the worker has a mission case 30 having a planted clutch case 181 configured so that the inter-stocks can be changed by operating the inter-stock lever 180 and the non-constant speed switching operation tool 190. In the variable inter-strain case 160 provided at the rear, since the inter-stock spacing is changed according to the idling rate of the traveling wheels 8 and 9, there are many idling of the traveling wheels 8 and 9 and less idling in the field 200. The spacing between stocks can be kept constant at any of the locations.

Further, according to the present embodiment, the rotation speeds of the internal gear 164 and the output shaft 155 of the planetary gear mechanism 161 are increased / decreased by the interstock adjustment motor 162 so that the interstocks can be changed, so that the interstocks are automatically interleaved. The mechanism to be changed can be miniaturized, and the range of change between stocks can be widened. Further, by changing the voltage applied to the inter-strain adjustment motor 162, the actual inter-strain inter-strain can be smoothly changed.

FIG. 13 is a schematic perspective view of the front portion of the wave breaker 110 on the left side according to another preferred embodiment of the present invention.

In this embodiment, the left side waveproof plate 110 having the protrusion 111 and the wide portion 112 at the lower front portion is formed by sheet metal processing a single metal plate.

Specifically, a part of the front part of the flat plate-shaped wave breaker 110 having the forward protruding portion 111 is outside in the width direction of the seedling transplanting machine 1 as shown by the alternate long and short dash line with an arrow in FIG. The wide portion 112 is formed by being bent into.

By bending a part of the flat plate-shaped wave breaker 110 in this way, a wave having substantially the opposite phase to the wave 116 (see FIG. 7) generated from the vicinity of the waterline of the breakwater plate 110 is formed. The wave-proof plate 110 provided with the projecting portion 111 for suppressing the spread of waves and the wide portion 112 can be manufactured at a lower cost.

Further, as shown in FIG. 13, since the wide portion 112 is formed on only one of the left and right sides of the wave barrier plate 110 on the left side (only the outside in the width direction of the seedling transplanting machine 1), the seedling transplanting machine 1 can move on the field. As the wave advances, a slight wave of water is formed on the inside of the breakwater plate 110 in the width direction from the front to the rear, and therefore, a wave of water is formed on the outside of the seedling transplanter 1 in the width direction. It is possible to further suppress the spread.

The description has been given to the left side waveproof plate 110 formed by sheet metal processing of a single metal plate, but the right side waveproof plate 110 is also configured in the same manner as the left side waveproof plate 110. The wave-proof plate 110 on the right side has a protruding portion 111 and a wide portion 112 formed by bending a part of the front portion of the flat metal plate to the outside (right side) in the width direction of the seedling transplanting machine 1. I have.

Therefore, as the seedling transplanting machine 1 moves forward, the wave is suppressed from spreading to the right from the wave barrier 110 on the right side, and the seedlings planted on the right side of the seedling transplanting machine 1 moving forward are prevented from falling. can do.

FIG. 14 is a schematic perspective view showing a state before the cover is attached to the ultrasonic sensor of the seedling transplanter 1 according to the embodiment shown in FIG. 13, and FIG. 15 is a schematic perspective view showing a state in which the cover is attached to the ultrasonic sensor. It is a schematic perspective view which shows the state.

The seedling transplanting machine 1 according to the present embodiment includes a pair of left and right ultrasonic sensors 120 and soil sensors (not shown), and a fertilizer application device while the seedling transplanting machine 1 advances in the field 200 while planting seedlings. 26 is configured to be able to supply an appropriate amount of fertilizer according to each location in the field 200 (variable fertilizer application).

14 and 15 show the vicinity of the ultrasonic sensor 120 provided on the left side of the seedling transplanting machine 1.

Further, in the present embodiment, the sensor mounting arm 131 to which the ultrasonic sensor 120 is mounted is mounted on the outer surface in the left-right direction of the frame 77 that supports the pair of left and right spare seedling stands 74 (see FIGS. 1 and 2). It is configured to be mountable on a fixed stay 122.

In addition, in this embodiment, the positions of the sensor mounting arm 131 and the ultrasonic sensor 120 with respect to the stay 122 in the front-rear direction and the left-right direction are respectively when the ultrasonic sensor 120 is used (during work) and when it is not used (during work). It is configured so that it can be switched between two stages (when stored).

Specifically, when the ultrasonic sensor 120 is used, the position of the sensor mounting arm 131 and the ultrasonic sensor 120 in the front-rear direction with respect to the stay 122 is forward, and the position in the left-right direction is on the right side (the side away from the stay 122). ) (The state shown in FIG. 15).

On the other hand, when the ultrasonic sensor 120 is not used, the positions of the sensor mounting arm 131 and the ultrasonic sensor 120 in the front-rear direction are switched to the rear, and the positions in the left-right direction are switched to the left side (the side close to the stay 122).

As shown in FIG. 14, the sensor mounting arm 131 has a substantially inverted U-shaped vertical cross-sectional shape, and an insertion hole 135 into which an ultrasonic sensor 120 is inserted and an ultrasonic sensor 120 are formed on the upper surface thereof. A through hole 137 through which a cable extending from the cable (not shown) is passed downward and two front-rear positioning through holes 133 and 134 for fixing to the stay 122 are formed. The two front-rear position-determining through holes 133 and 134 are provided side by side in the front-rear direction.

A rod-shaped member 138 extending rearward is fixed to the rear portion of the sensor mounting arm 131.

On the other hand, the stay 122 has a fixing portion 125 fixed to the right side surface of the frame 77 and extending in the front-rear direction, a sensor mounting arm mounting portion 126 extending from the front upper portion of the fixing portion 125 to the left, and a rear end of the fixing portion 125. It is provided with a left-right movement restricting unit 127 extending from the unit to the left.

The sensor mounting arm mounting portion 126 is formed with two left-right positioning through holes 128 and 129 arranged side by side in the left-right direction.

Two notches 118 and 119 arranged in the left-right direction are formed in the lower portion of the left-right movement restricting portion 127, and when the sensor mounting arm 131 is attached to the stay 122, the rod-shaped member 138 is shown in FIG. As described above, the horizontal movement of the rod-shaped member 138 and the sensor mounting arm 131 is restricted by passing through the inside of the notch 118 or 119.

When the sensor mounting arm 131 and the ultrasonic sensor 120 are mounted at a storage position close to the frame 77 in the left-right direction, the rod-shaped member 138 is passed through the notch 119.

On the other hand, when the sensor mounting arm 131 and the ultrasonic sensor 120 are mounted at working positions separated from the frame 77 in the left-right direction, the rod-shaped member 138 is formed in the notch 118 as shown in FIG. Is passed through.

Further, in the present embodiment, a cover 121 that prevents rainwater or muddy water from hitting the ultrasonic sensor 120 is configured to be mountable on the sensor mounting arm 131.

Specifically, holes 132 for mounting the cover are formed on the left and right surfaces of the sensor mounting arm 131, and holes 123 are formed on the left and right surfaces of the cover 121.

Therefore, it is shown in FIG. 15 by inserting a bolt 124 into the hole 123 of the cover 121 and the hole 132 for mounting the cover with the cover 121 covered on the ultrasonic sensor 120 mounted on the sensor mounting arm 131. As described above, the cover 121 can be attached to the sensor mounting arm 131.

As shown in FIGS. 14 and 15, the upper portion of the cover 121 has a shape that is inclined forward, and mud and water do not collect in the vicinity of the ultrasonic sensor 120. Therefore, the ultrasonic waves are caused by the mud and water. It is possible to prevent a situation in which sensing by the sensor 120 is obstructed. Further, in the present embodiment, the bolt 124 is composed of a tamper-proof bolt to prevent the ultrasonic sensor 120 from being stolen.

In this way, when the sensor mounting arm 131 to which the cover 121 is mounted is mounted on the stay 122, the rod-shaped member 138 is first passed through the left and right notches 118 or 119 by the operator. The left and right position through holes 128 or 129 and the front and rear position determination through holes 133 or 134 provided on the upper surface of the sensor mounting arm 131 are vertically aligned.

Next, the bolt 139 is screwed into the nut 140 with the bolt 139 inserted into the left and right position through holes 128 or 129 and the front and rear position determination through holes 133 or 134, and the sensor mounting arm 131 stays. Attached to 122.

Here, below the upper surface of the sensor mounting arm mounting portion 126 and the sensor mounting arm 131, the bolt 139 is passed through the spring 141, and the rod-shaped member 138 is not in the through hole but in the notch 118 or 119. When an impact is applied to the sensor mounting arm 131 or the ultrasonic sensor 120 from above, the spring 141 temporarily lowers the ultrasonic sensor 120, the sensor mounting arm 131, and the rod-shaped member 138. Therefore, the impact (force) applied to the ultrasonic sensor 120 and the sensor mounting arm 131 can be released in the vertical direction.

In addition, a bolt 139 is inserted through one of the left and right position through holes 128 or 129 and one of the front and rear positioning through holes 133 or 134, and a rod-shaped member 138 is inserted into one of the left and right notches 118 or 119. Since it is passed through, the horizontal movement of the rod-shaped member 138 is restricted, and the horizontal movement of the ultrasonic sensor 120 is also restricted.

In this embodiment, when the ultrasonic sensor 120 is used, the rod-shaped member 138 is passed through the notch 118 on the left side, and the front-rear position-determining through hole 134 on the rear side and the left-right position on the left side. Bolts 139 are inserted through the determination through holes 128 (see FIG. 14).

As a result, the ultrasonic sensor 120 is provided relatively forward and to the left as compared with when not in use.

On the other hand, when the ultrasonic sensor 120 is not used, the rod-shaped member 138 is passed through the notch 119 on the right side, and the front-rear position-determining through hole 133 on the front side and the left-right position-determining through hole 129 on the right side. The bolt 139 is inserted into the.

As a result, the ultrasonic sensor 120 is provided relatively rearward and to the right as compared with the time of use. In this way, since the ultrasonic sensor 120 can be attached closer to the cockpit 48 (see FIGS. 1 and 2), the ultrasonic wave is not performed when the work using the ultrasonic sensor 120 is not performed. The sensor 120 can be protected.

Further, in the present embodiment, an ultrasonic sensor 120 configured to be able to switch the positions in the front-rear direction and the left-right direction is used in the front part of the seedling transplanting machine 1 as described above, and the elevating hydraulic cylinder 12 is used. The raising and lowering operation of the seedling planting unit 63 can be executed at an earlier timing than when the detection signal of the float sensor 33 is used.

Specifically, the seedling transplanting machine 1 calculates the unevenness of the field 200 based on the detection signals of the ultrasonic sensor 120 and the acceleration sensor (not shown), and the position of the seedling transplanting machine 1 acquired by the GNSS receiver 130. The seedling planting unit 63 is manually or automatically traveled in the field 200 while mapping together with the information, and at the timing when the traveling wheels 8 and 9 pass through the unevenness on the field based on the created map of the unevenness. Is raised and lowered.

Specifically, the pair of left and right ultrasonic sensors 120 are configured to be located in front of the pair of left and right front wheels 9 when they are provided at working positions (see FIG. 15), and while mapping, they are configured to be located in front of the pair of left and right front wheels 9. While traveling, the posture of the seedling transplanter 1 is calculated based on the detection signal by the acceleration sensor after the constant pulse (timing when the front wheel 8 reaches the detected field 200) from the detection by the ultrasonic sensor 120. do.

At this time, when the seedling transplanting machine 1 is tilted, the controller 87 responds to the tilting of the posture of the seedling transplanting machine 1 after a time corresponding to the value obtained by subtracting the response time equivalent pulse from the constant pulse elapses. The output value is output to the electro-hydraulic valve 88, and the seedling planting portion 63 is moved up and down by the operation of the elevating hydraulic cylinder 12.

On the other hand, when the seedling transplanting machine 1 is not tilted, the vertical position of the seedling planting portion 63 is held.

FIG. 16 is a schematic perspective view of the vicinity of the diff lock motor 16 of the seedling transplanting machine 1 according to the embodiment shown in FIG.

In the present embodiment, by driving the diff lock motor 16, the diff lock arm 19 acts on the diff lock clutch 23, and the left and right front wheel axles 17 and 18 (a state in which the differential rotation in the figure is allowed and a state in which the differential rotation is restricted) are used. It is configured to be switchable between.

Further, as shown in FIG. 16, in the present embodiment, the diff lock pedal 62 is provided in the control unit 49, and further, in addition to the diff lock arm 19 that acts on the diff lock clutch 23 by driving the diff lock motor 16. A diff lock arm 66 that acts on the diff lock clutch 23 by operating the diff lock pedal 62 is separately provided.

Therefore, the operator operates the diff lock pedal 62 at an arbitrary timing to limit the differential rotation of the left and right front wheel axles 17 and 18 (operate the diff lock) or allow the differential rotation (release the diff lock). be able to.

Further, a limit switch (not shown) is provided in the vicinity of each diff lock arm 19 and 66, and the diff lock pedal 62 is operated by an operator to limit the differential rotation of the left and right front wheel axles 17 and 18. In this case, the diff lock motor 16 is configured not to be driven until the differential rotation is allowed.

Further, when the differential rotation of the left and right front wheel axles 17 and 18 is restricted (operation of the differential lock) by the operator operating the differential lock pedal 62 or by driving the differential lock motor 16, the controller 87 limits the differential rotation. It is configured to detect it based on the detection signal from the switch, acquire the position information of the seedling transplanting machine 1 from the GNSS receiver 130, and store it in the storage unit 93.

Therefore, when the combine is automatically driven at the time of harvesting rice, the position information on the diff lock stored at the time of planting the seedlings by the seedling transplanting machine 1 is utilized to create an automatic traveling route for avoiding ruts and muddyness. It will be possible to generate.

On the other hand, in the seedling transplanting machine 1 according to the above embodiment, after the steering handle 56 is steered (that is, when turning) beyond a predetermined angle by automatic traveling on the first route, the traveling wheels 8 and 9 When the idling of the left and right front wheel axles 17 and 18 is detected, the differential rotation of the left and right front wheel axles 17 and 18 is automatically restricted.

On the other hand, in the present embodiment, in addition to the case where the seedling transplanting machine 1 makes a turning trip, when the seedling transplanting machine 1 travels straight, the seedling transplanting machine 1 travels based on the position information of the seedling transplanting machine 1 and the rotation speed of the axle 82 of the rear wheel 9. Even when slipping of the wheels 8 and 9 is detected, the differential rotation of the left and right front wheel axles 17 and 18 is automatically restricted, and the position information at that point is stored in the storage unit 93. ..

That is, in this embodiment, it is not a requirement that the steering handle 56 be steered beyond a predetermined angle when the differential rotation is automatically restricted.

Further, while the differential rotation of the left and right front wheel axles 17 and 18 is automatically restricted regardless of whether the seedling transplanting machine 1 is turning or traveling straight by the automatic traveling, the controller 87 is used. The seedling transplanting machine 1 is configured to allow the seedling transplanting machine 1 to deviate from the automatic traveling path within a predetermined range.

With this configuration, the seedling transplanter 1 can preferentially recover from ruts and muddy fields on the field in a state where the differential rotations of the left and right front wheel axles 17 and 18 are restricted. Further, in a state where the differential rotation of the left and right front wheel axles 17 and 18 is restricted, the seedling transplanting machine 1 does not need to make a small turn, and the front and rear traveling wheels 8 and 9 and the axles (front wheel axles 17 and 18 and the rear wheels) do not need to make a small turn. It is possible to prevent a large load from being applied to the axle 82).

Further, in the seedling transplanting machine 1 according to the present embodiment, when the differential rotation of the left and right front wheel axles 17 and 18 is automatically restricted and the idling of the traveling wheels 8 and 9 is eliminated, the following is performed. , Can return to the automatic driving route.

FIG. 17 shows from the time when the differential rotation of the left and right front wheel axles 17 and 18 according to the embodiment shown in FIG. 13 is allowed on the first path until the seedling transplanter 1 returns to the automatic traveling path. It is a flowchart which shows the control procedure.

Further, FIG. 18 is a schematic plan view showing a traveling path from when the differential rotation of the left and right front wheel axles 17 and 18 is allowed on the first path until the seedling transplanting machine 1 returns to the automatic traveling path. Is.

After the idling of the traveling wheels 8 and 9 is eliminated on the first path and the differential rotation of the left and right front wheel axles 17 and 18 is allowed, the controller 87 first receives the seedling transplanter from the GNSS receiver 130. Acquire the position information of 1 (step SS1).

Next, the controller 87 acquires the data of the automatic traveling route from the storage unit 93 (step SS2).

When the position information of the seedling transplanting machine 1 and the data of the automatic traveling route are acquired, the controller 87 calculates the difference between them (step SS3).

In this way, after calculating the difference between the current location of the seedling transplanting machine 1 and the automatic traveling path, the controller 87 determines that the seedling transplanting machine 1 is at a point where the differential rotation of the left and right front wheel axles 17 and 18 is automatically restricted. It is determined whether or not it is in the area where the seedlings are planted (whether or not it is in the central area 210) when traveling on the first route (step SS4).

As a result of the judgment, when the point where the differential rotation of the left and right front wheel axles 17 and 18 is automatically restricted is within the area where the seedlings are planted when traveling on the first route (first route). When traveling straight through the central region 210, see FIG. 8), as shown in FIG. 18 (a), the differential rotation of the left and right front wheel axles 17 and 18 is automatically restricted instead of the automatic traveling path. The vehicle automatically travels on the shortest route from the designated point to a point 10 m away (step SS5).

By configuring the vehicle so as not to travel on the automatic traveling path for 10 m in this way, the traveling wheels 8 and 9 slip and travel straight from the point where the differential rotation of the left and right front wheel axles 17 and 18 is restricted. It is possible to avoid ruts that are presumed to extend in the direction (north-south direction in FIG. 8), and it is possible to prevent the traveling wheels 8 and 9 from slipping again.

On the other hand, as a result of the judgment, when the point where the differential rotation of the left and right front wheel axles 17 and 18 is automatically restricted is outside the area where the seedlings are planted when traveling on the first path. (When turning around the peripheral region 212 or 214 in the first route, see FIG. 8), as shown in FIG. 18 (b), the automatic traveling route is changed to the first on the automatic traveling route from the current location. The shortest route to the nearest of the first planting start position 205 and the second planting start position 206 is automatically traveled (step SS6).

In this way, the seedlings are partially planted in the central region 210 of the field 200 by being configured to return to the first planting start position or the second planting start position on the automatic traveling path. It is possible to prevent the situation that is not done.

In addition, by configuring to return to the planting start position, the traveling wheels 8 and 9 again with ruts and mud compared to the case of returning to a place on the automatic traveling path and closer to the diff lock point. Can be suppressed from spinning.

19 (a) is a schematic perspective view of the vicinity of the wave barrier 110 on the left side according to still another preferred embodiment of the present invention, and FIG. 19 (b) is the left side shown in FIG. 19 (a). It is a schematic horizontal sectional view in the vicinity of the through hole 45 of the wave breaker 110.

As shown in FIG. 19 (a), in this embodiment, the left wave breaker 110 is attached to the left portion of the cover 28 of the left ground leveling rotor 32, from the central leveling rotor 31 (see FIG. 4). It is possible to block the wave of water spreading to the left (shown by the alternate long and short dash line with an arrow in FIG. 19A) and the wave spreading to the left from the leveling rotor 32 on the left side.

Further, in the present embodiment, the wave barrier plate 110 on the left side is formed by bending the front portion thereof to the left (outside in the width direction of the seedling transplanting machine 1) as shown in FIG. 19 (a). A bent portion 113 is provided.

As a result, as the seedling transplanting machine 1 moves forward, as shown by the alternate long and short dash line with an arrow, the bent portion 113 from the front left side of the wave barrier plate 110 on the left side to the right side (width of the seedling transplanting machine 1). A flow of water is formed (inside the direction).

Therefore, it is possible to prevent the mud from spreading outward in the width direction of the seedling transplanting machine 1 when the mud springs out as the seedling transplanting machine 1 runs.

Further, as shown by diagonal lines in FIG. 19B, in front of the right side of the three overflow prevention through holes 45 provided in the wave barrier plate 110 on the left side, the seedling transplanting machine 1 is located from the inside to the outside in the width direction. A guide 114 is provided to prevent the flow of water to.

Each guide 114 has a shape that extends rearward after extending inward (right side) in the width direction of the seedling transplanting machine 1 from the position in front of each through hole 45, that is, has a substantially L-shape in a plan view. When the seedling transplanting machine 1 travels forward, it regulates the flow of water on the field from the inner front to the outer rear in the width direction of the seedling transplanting machine 1, but as shown by the broken line with an arrow, the seedling transplanting It is configured to allow the flow of water on the field from the outer front to the inner rear in the width direction of the machine 1.

With this configuration, as the seedling transplanting machine 1 advances, a flow of water held on the field is formed from the outer front to the inner rear in the width direction of the seedling transplanting machine 1, so that the left side It is possible to prevent the water wave generated when the wave breaker 110 moves forward from spreading to the left side of the seedling transplanting machine 1.

The three overflow prevention through holes 45 are configured to have a sufficient size so that water or mud on the overflowing field can pass to the left from each through hole 45.

Although the left side waveproof plate 110 according to the present embodiment has been described in detail above, the right side waveproof plate 110 is also configured in the same manner and is formed by being bent outward in the width direction of the seedling transplanting machine 1. The bent portion 113 and the substantially L-shaped guide 114 formed in the vicinity of each through hole 45 can form a water flow from the outside to the inside in the width direction of the seedling transplanting machine 1.

FIG. 20 is a schematic perspective view of the vicinity of the sensor mounting arm 131 to which the ultrasonic sensor of the seedling transplanting machine 1 according to the embodiment shown in FIG. 19 is mounted.

FIG. 20 shows the vicinity of the sensor mounting arm 131 provided on the left side of the seedling transplanting machine 1.

As shown in FIG. 20, in this embodiment, a spring 141 is provided between the stay 122 fixed to the frame 77 supporting the preliminary seedling stand 74 (see FIG. 1) and the sensor mounting arm 131. The front portion of the sensor mounting arm 131 and the ultrasonic sensor 120 are configured to be slightly swingable in the left-right direction with respect to the stay 122.

Therefore, when an impact is applied to the sensor mounting arm 131 or the ultrasonic sensor 120 from the outside (left side) in the width direction of the seedling transplanting machine 1, the force can be released (distributed) in the left-right direction.

Further, in the present embodiment, as shown in FIG. 20, the pin 142 is inserted into the through holes 143 and 144 provided in the rear portion of the stay 122 and the rear portion of the sensor mounting arm 131, respectively.

Therefore, the positions of the sensor mounting arm 131 and the ultrasonic sensor 120 in the front-rear direction can be maintained.

21 is a drawing showing the left side float 39 of the seedling transplanting machine 1 according to the embodiment shown in FIG. 19, and FIG. 21 (a) is a schematic perspective view of the left side float 39. 21 (b) is a schematic front view of the left side float 39, and FIG. 21 (c) is a substantially left side view of the left side float 39.

As shown in FIGS. 21 (a) and 21 (c), the front lower portion of the left side float 39 according to the present embodiment and the left end portion (outside in the width direction of the seedling transplanting machine 1) are rounded. A protruding portion 52 is provided.

The protruding portion 52 is configured to project forward and to the left (outside in the width direction of the seedling transplanting machine 1) and to be located below the waterline of the side float 39.

Here, also in this embodiment, as in the embodiment shown in FIGS. 1 to 12, the seedling planting section 63 is based on the detection signal of the float sensor 33 provided in the center float 38 (see FIG. 4). The height position of is automatically adjusted according to the unevenness of the field. As a result, the draft position of the left side float 39 is maintained, and the protrusion 52 continues to be located below the water surface.

Therefore, as the seedling transplanter 1 moves forward, when the left side float 39 moves forward, the wave generated in the vicinity of the waterline in the left side float 39 is the wave generated in the protrusion 52. Since it is canceled by, it is possible to suppress the spread of the wave to the left side of the left side float 39 (outside in the width direction of the seedling transplanting machine 1).

Further, since it is possible to suppress the spread of waves to the left of the left side float 39 in this way, the rear portion of the wave breaker 110 attached to the rotor cover 28 of the left ground leveling rotor 32 is shown in FIG. As shown in the above, the structure is short, and it is not necessary to extend the side float 39 rearward to the front-rear position of the left side float 39, so that the manufacturing cost of the wave-proof plate 110 can be kept low.

Further, in the present embodiment, as shown in FIG. 21B, the protruding portion 52 is provided only on the left portion of the left side float 39, and is not provided on the right portion.

Therefore, a wave from the front to the rear is formed on the right side of the side float 39 on the left side (inside in the width direction of the seedling transplanting machine 1). It is possible to further suppress the wave generated from 31 or the like from spreading outward in the width direction.

The left side float 39 has been described in detail above, but the right side float 39 is also configured in the same manner, and the front lower part and the right part of the right side float 39 (outside in the width direction of the seedling transplanter 1). Is provided with protrusions 52 protruding forward and to the right, so that it is possible to suppress the spread of water waves held on the field to the right of the side float 39 on the right side.

22 (a) is a schematic perspective view showing the rear wheel of the conventional seedling transplanting machine 1, and FIG. 22 (b) shows the rear wheel of the seedling transplanting machine 1 according to the embodiment shown in FIG. It is a schematic perspective view.

As shown in FIG. 22 (a), the conventional rear wheel includes a hub located at the center of rotation thereof, a rim located at the outer peripheral portion thereof, and a plurality of spokes connecting the hub and the rim. Since the surface of the iron ring-shaped member was formed by wrapping rubber around it in order to give it a grip, the weight of the entire rear wheel tended to be excessively heavy.

Also, especially in fields where sticky soil is deposited, the space formed between the hub and multiple spokes and rims is clogged with mud, making it impossible for the seedling transplanter to run, and as a result, it sinks into the field. , The planting work of seedlings was sometimes interrupted.

On the other hand, since the seedling transplanting machine 1 according to the present embodiment is equipped with a balloon tire 83 as a rear wheel, when traveling on a field, mud is held like a conventional rear wheel. There is no.

Further, the balloon tire 83 is made of resin, so that the rear wheels can be formed lightweight and have buoyancy.

In this embodiment, the strength of the balloon tire 83 is improved by the hub insert.

The present invention is not limited to the above embodiments, and various modifications can be made within the scope of the invention described in the claims, and these are also included in the scope of the present invention. Needless to say.

For example, in each of the embodiments shown in FIGS. 1 to 22, a seedling transplanter is mentioned as an example of an agricultural work vehicle, but the agricultural work vehicle according to the present invention is a combine or a tractor. And so on.

For example, in the embodiment shown in FIGS. 1 to 12, the front and lower portions of the pair of left and right wave breaker plates 110 are projected forward to form the protruding portion 111, and further, on one side surface of the protruding portion 111. Although the wide portion 112 with chamfered processing is attached to the columnar member, it is not always necessary to configure the wide portion 112 separately from the protruding portion 111, and it is not always necessary to configure the wide portion 112 separately from the projecting portion 111, as in the bulbous bow of a ship. By forming a roundness that bulges forward and outward in the width direction of the machine body (outside in the width direction of the seedling transplanting machine 1) in the front lower part of the pair of left and right wave breaker 110, the protruding portion 111 and the wide portion 112 are made into the breakwater plate 110. It may be provided. That is, the projecting portion 111 and the wide portion 112 may be integrally formed, and in this case, in the portion provided in the front lower portion of the wave blocking plate and projecting forward, the other wave blocking plate is formed. The wide portion is the portion that extends outward in the width direction from the portion.

Further, in the embodiment shown in FIGS. 1 to 12, the front wheel rotation sensor 21 for detecting the rotation speed of the front wheel 8 is configured to be able to detect the rotation speed of the front wheel axles 17 and 18. If the number of revolutions of the front wheel axles 17 and 18 can be detected, it is not always necessary to detect the number of revolutions of the front wheel axles 17 and 18.

Further, in the embodiment shown in FIGS. 1 to 12, when the idling of the traveling wheels 8 and 9 is detected, the differential rotation of the front wheel axles 17 and 18 (and the front wheel 8) is limited. However, it may be configured to limit the differential rotation of the left and right rear wheel axles 82, and is configured to limit the differential rotation of both the front wheel axles 17 and 18 and the rear wheel axle 82, respectively. You may.

Further, in the embodiment shown in FIGS. 1 to 12, the diff lock motor 16 is configured to limit the differential rotation of the left and right front wheel axles 17 and 18 by driving the diff lock motor 16. A holding mechanism may be provided inside, or a ratchet mechanism may be provided outside the diff lock motor 16.

Further, in the embodiment shown in FIGS. 1 to 12, the waveproof plate 110 provided with the projecting portion 111 and the wide portion 112 is connected to the planting depth frame 42 and the planting portion frame via the parallel link 46. However, the wave breaker 110 may be directly attached to the outer surface of the side float 39 in the width direction of the machine body so as to maintain the position of the waterline.

Further, in the embodiment shown in FIGS. 1 to 12, as shown in FIG. 7, the wave 116 generated from the vicinity of the waterline of the breakwater plate 110, and the wave 116 generated from the projecting portion 111 and the wide portion 112. The projecting portion 111 and the wide portion 112 are configured so that the waves are substantially out of phase with each other, but it is not always necessary to have the opposite phase as clear as shown in FIG. 7, and the wave 116 is made smaller. If the phases of the waves are out of phase with each other to such an extent that the waves can be prevented from spreading to the left and right of the seedling transplanting machine 1.

Further, in the embodiment shown in FIGS. 1 to 12, the automatic running can be started by turning on the automatic running on / off switch 79 by the worker, but the worker transplants seedlings. It is not always necessary to be on board the machine 1, and a tablet terminal or the like is separately provided so as to be able to communicate with the seedling transplanting machine 1, and a worker who stands by on the shore of the field 200 or the like can use the seedling transplanting machine on the tablet or the like. It may be configured so that the start operation of the automatic running of 1 can be performed.

Further, in the embodiment shown in FIGS. 1 to 12, it is configured to calculate an automatic traveling route by manually traveling in the peripheral regions 211 to 213 along three sides of a substantially rectangular field. However, it is not always necessary to calculate the automatic travel route by manual travel of the seedling transplanting machine 1, and the data of the automatic travel route may be configured to be downloadable from the server, and a tablet terminal or the like is separately provided. After the range of the field is specified by the operator on the map displayed on the terminal, the controller 87 may be configured to calculate the automatic travel route within the specified range.

Further, in the embodiment shown in FIGS. 1 to 12, as shown in FIG. 9, when it is determined that the vehicle is turning during automatic traveling, the traveling wheels 9 and 10 are idling (slip). In this case, it is configured to automatically limit the differential rotation of the left and right front wheel axles 17 and 18, but when it is determined that it is turning during manual driving by the operator. Therefore, even when slipping of the traveling wheels 8 and 9 is detected, the differential rotation of the left and right front wheel axles 17 and 18 may be automatically restricted.

Further, in the embodiment shown in FIGS. 1 to 12, the actual airframe in which the movement distance of the airframe estimated from the detection signal of the rear wheel rotation sensor 29 is calculated from the position information acquired by the GNSS receiver 130. It is configured to determine the idling of the traveling wheels 9 and 10 depending on whether or not it matches the moving distance of the above, but when the estimated moving distance of the aircraft completely matches the actual moving distance of the aircraft. It is not always necessary to configure the traveling wheels 8 and 9 to determine that they are not idling, and only when the estimated travel distance of the aircraft is significantly longer than the actual travel distance of the aircraft. In addition, it may be configured to determine that the traveling wheels 8 and 9 are idling, and if not, it is determined that the traveling wheels 8 and 9 are not idling. In other words, the range in which it is determined that the traveling wheels 8 and 9 are not idling may be provided with a width. Further, in calculating the estimated movement distance of the aircraft, if the estimated movement distance is corrected according to the steering amount of the steering handle 56, the accuracy of slip detection can be improved. Further, the elimination of the idling of the traveling wheels 8 and 9 may be configured to be detected based on the detection signal (pulse) of the front wheel rotation sensor 21 provided on the front wheel axles 17 and 18. In this case, for example, the diff lock may be turned off when the front wheel 8 makes 1/2 rotation after the operation of the diff lock (restriction of the differential rotation of the front wheel axles 17 and 18).

Further, in the embodiment shown in FIGS. 1 to 12, it is configured to determine the turning of the seedling transplanting machine 1 depending on whether or not the steering angle of the steering handle 56 exceeds a predetermined angle. However, the turning of the seedling transplanting machine 1 may be determined depending on whether or not the steering angle of the steering handle 56 is equal to or greater than a predetermined angle.

Further, in the embodiment shown in FIGS. 1 to 12, the idling of the traveling wheels 8 and 9 is detected based on the position information acquired by the GNSS receiver 130 and the detection signal of the rear wheel rotation sensor 29. However, it is not always necessary to use the GNSS receiver 130 and the rear wheel rotation sensor 29 as the slip detection means. For example, a torque sensor for detecting the torque of the traveling wheels 8 and 9 or the axle is separately provided. If the torque of the traveling wheels 8 and 9 located on the outer side or the axle is less than a predetermined value at the time of turning, it may be configured to determine that the traveling wheels 8 and 9 are idling. In this case, the diff lock motor 16 may be further configured to stop driving when the torque of the traveling wheels 8 and 9 or the axle returns.

Further, in the embodiment shown in FIGS. 1 to 12, the drive of the differential lock motor 16 is stopped when the values of the rotation speeds of the left and right front wheel axles 17 and 18 output from the front wheel rotation sensor 21 are equal. However, the timing at which the differential lock motor 16 is stopped is not limited to this, and the differential lock motor 16 may be configured to stop when it operates by a constant angle or a constant pulse. The torque sensor may be configured to stop the differential lock motor 16 especially when the torques of the traveling wheels 9 and 10 on the inner side of the turn are returned.

Further, in the embodiment shown in FIGS. 1 to 12, when the seedling transplanting machine 1 is turned, if the traveling wheels 8 and 9 are idling, the left and right front wheel axles 17 are automatically used. , 18 is configured to limit the differential rotation (diff lock), but an auto on / off switch for switching whether to allow the diff lock by the controller 87 may be provided in the vicinity of the driver's seat or the like. Further, a differential differential switch that forcibly limits the differential rotation of the front wheel axles 17 and 18 by being operated at any time may be provided.

Further, in the embodiment shown in FIGS. 1 to 12, the diff lock is released when it can be confirmed from the position information that the seedling transplanting machine 1 has moved a distance corresponding to the rotation speed of the rear wheel rotation sensor 29. However, the timing for releasing the diff lock is not limited to this, and the diff lock is released when it can be confirmed that the seedling transplanting machine 1 is moving based on the position information. It may be configured to do so.

Further, in the embodiment shown in FIGS. 1 to 12, the slip ratio of the traveling wheels 8 and 9 is determined by the actual moving distance of the seedling transplanting machine 1 calculated from the position information acquired by the GNSS receiver 130. Although it is configured to be calculated from the moving distance of the seedling transplanting machine 1 estimated from the rotation speed of the axle 82 (see FIG. 1) of the rear wheel 9 on the outer turning side detected by the rear wheel rotation sensor 29, the traveling wheel. The calculation method of the slip ratios of 8 and 9 is not limited to this, and for example, the slip ratio is measured using a torque sensor, and the adjustment amount between stocks is determined by the torque down amount (ratio with the drive shaft rotation pulse). You may.

Further, in the embodiment shown in FIGS. 1 to 12, it is configured to drive or stop the interstock adjustment motor 162 configured by the variable speed motor according to the idling rate of the traveling wheels 8 and 9. However, it is not always necessary to configure the inter-stock adjustment motor 162 with a variable speed motor.

Further, in the embodiment shown in FIGS. 1 to 12, the detection signal of the inter-stock sensor 97 is obtained by operating the inter-stock lever 180 and the non-constant speed switching operation tool 190 shown in FIG. 11 by the operator. Based on the above, after the stock spacing is adjusted stepwise in the planting clutch case 181, the stock spacing is automatically adjusted in the variable stock spacing case 160 on the downstream side thereof, but the stock spacing lever 180 and the non-stock spacing are not adjusted. An actuator for driving the constant velocity switching operation tool 190 is separately provided, and based on the idling rate of the traveling wheels 8 and 9 in two stages, the upstream side (inside the planting clutch case 181) and the downstream side (inside the variable stock case 160). , The stock spacing may be configured to automatically adjust to the length initially set by the stock spacing lever 180 and the non-constant speed switching actuator 190 (or the length set on the monitor 61). In this case, for example, in the planting clutch case 181 the stocks are changed stepwise by 20%, and in the variable stock case 160, the stocks can be continuously changed within a range of plus or minus 10%, and the stocks are automatically changed. When the calculated slip ratio of the traveling wheels 8 and 9 is equal to or higher than a predetermined value (for example, 10%), the slip is adjusted in the planting clutch case 181 and then finely adjusted in the variable interstock case 160 to slip. If the rate is less than a predetermined value, it may be configured to be adjusted only within the variable interstock case 160. With this configuration, during the planting run of the seedling transplanting machine 1, the seedling stocks can be accurately and steplessly switched according to the set value.

Further, every time the turning of the seedling transplanting machine 1 is detected based on the detection signal of the steering sensor 58, in the planted clutch case 181 based on the average idling rate of the traveling wheels 8 and 9 during straight running before turning. , The stocks may be automatically configured to approach the set value, or the stocks may be configured to be configurable on the monitor 61 or the like. With this configuration, seedlings can be planted accurately between the set strains.

Further, in each of the embodiments shown in FIGS. 1 to 22, the protruding portion 111 of the wave barrier 110 or the protruding portion 52 of the side float 39 both follow the ascending / descending of the seedling planting portion 63, and the field. Although it is configured to be located below the water surface of the water (field water) stored on the 200, it is not always necessary to configure the protrusions 111 and 52 so as to always be located below the water surface. Only when the watering position is higher than the predetermined height position (when the amount of water on the rice field is large and the wave is easy to spread), the protrusion 111 or the protrusion 52 is located below the water surface and the wave can be suppressed. It may be configured. With this configuration, when the planting run is performed while the water level of the water stored on the field 200 is in the field scene, the lower part of the wave barrier 110 or the side float 39 is from the field surface. It is also possible to prevent the wave-proof plate 110 or the side float 39 from sinking downward, and to prevent the trace of the movement of the wave-proof plate 110 or the side float 39 from remaining in the field.

Further, in the embodiment shown in FIGS. 13 to 18, the differential rotation of the left and right front wheel axles 17 and 18 is determined for the determination of the return route to the automatic traveling path after the diff lock is released, as shown in FIG. It is configured so that the point where is automatically restricted depends on the judgment result of whether or not it is within the area where the seedlings are planted (step SS4), but the difference between the left and right front wheel axles 17 and 18. After the dynamic rotation is automatically restricted, the automatic travel route after the differential rotation is released depends on whether the point where the differential rotation is automatically allowed (diff lock release point) is within the area where the seedlings are planted. It may be configured to determine the return route to.

Further, in the embodiment shown in FIGS. 13 to 18, as shown in FIG. 17, the operation points of the diff locks of the left and right front wheel axles 17 and 18 are within the planting area (central area) of the first path. It is configured to determine the return route depending on whether or not it is within 210), but when the diff locks of the left and right front wheel axles 17 and 18 are canceled, it returns to the automatic driving route by the shortest route. It may be configured as follows. Similarly, by configuring in this way, the influence on agricultural work (planting work of seedlings, etc.) can be minimized.

Further, in the embodiment shown in FIGS. 13 to 18, as shown in FIG. 16, two diff lock arms 19 and 66 are arranged on the front side of the drawing of the diff clutch 23, but one diff lock is provided. The arm may be arranged on the back side of the drawing of the other diff lock arm so as to be located coaxially with each other.

Further, in the embodiment shown in FIGS. 13 to 18, based on the rear wheel rotation sensor 29 and the GNSS receiver 130, the idling of the traveling wheels 8 and 9 is detected, and the left and right front wheel axles 17 and 18 are differential. Although it is configured to limit the rotation, the seedling transplanter 1 is provided with a depth sensor and a camera in the field to detect the amount of water held on the field and the muddy front of the seedling transplanter 1. If it is predicted that traveling will be difficult, the differential rotation of the left and right front wheel axles 17 and 18 may be restricted in advance.

Further, in the embodiment shown in FIGS. 13 to 18, the unevenness of the field 200 is mapped and created based on the detection signals of the ultrasonic sensor 120 and the acceleration sensor shown in FIGS. 14 and 15. Although it is configured to move the seedling planting portion 63 up and down based on the map, it is not always necessary to map the unevenness of the field 200, and the traveling wheel is based on the detection signal of the rear wheel rotation sensor 29. When the 8 and 9 reach the unevenness of the field 200, the seedling planting portion 63 may be configured to move up and down.

Further, in the embodiment shown in FIGS. 13 to 18, in consideration of the radial detection region of the ultrasonic sensor 120, the sensor mounting arm 131 and the stay 122 are used to separate the ultrasonic sensor 120 from the machine body. However, when a laser distance meter having high directivity is used instead of the ultrasonic sensor 120, the sensor can be arranged close to the machine body.

Further, in the embodiment shown in FIGS. 19 to 22, as shown in FIG. 19, the bent portions 113 are formed on the front portions of the pair of left and right wave barrier plates 110, respectively, but the bent portions 113 are formed. It is not always necessary to form the good. In this case, by providing the wide portion 112 only on the outer surface in the width direction of the machine body, the flow of the rice field water is formed on the inner side in the width direction of the machine body, and the wave of the rice field water spreads to the left and right of the seedling transplanting machine 1. It can be suppressed.

Further, in the embodiment shown in FIGS. 19 to 22, the wave barrier 110 is provided so as to cover the side of the left and right leveling rotor 32 as shown in FIG. 19, but the left and right leveling rotor The wave breaker 110 may be configured to be longer rearward so that the waves generated by the side float 39 provided behind the 32 can be blocked at the same time.

Further, in the embodiment shown in FIGS. 19 to 22, as shown in FIG. 21, the front portion of the front portion of the left and right side float 39 in the width direction of the aircraft, that is, the front portion on the left side of the left side float 39. A bulge (protruding portion 52) is formed on each of the portion and the front portion on the right side of the right side float 39, and further, bulges are formed on the left and right ends of the front portion of the center float 38, respectively, to form a seedling transplanting machine. As 1 moves forward, the waves may be suppressed from spreading to the left and right of the aircraft.

1 Seedling transplanter 2 Traveling vehicle body 3 Main frame 4 Belt type power transmission mechanism 5 Elevating link device 6 Rear frame 7 Engine 8 Front wheels 9 Rear wheels 10 Link base frame 11 Elevating link arm 12 Elevating hydraulic cylinder 13 Front wheel final case 14 Rear wheel transmission Shaft 15 Differential mechanism 16 Diff lock motor 17 Front wheel axle 18 Front wheel axle 19 Diff lock arm 20 Auxiliary transmission mechanism 21 Front wheel rotation sensor 22 On / off pin 23 Diff clutch 24 Auxiliary shift lever 25 Hydraulic continuously variable transmission 26 Fertilizer application device 27 Fertilizer hopper 28 Rotor Cover 29 Rear wheel rotation sensor 30 Mission case 31 Central leveling rotor 32 Left and right leveling rotor 33 Float sensor 34 Feeding device 35 Forward / backward lever 36 Forward / backward lever sensor 37 Drive shaft 38 Center float 39 Side float 40 Fertilizer hose 41 Rotor blade 42 Planting Depth frame 43 First arm 44 Second arm 45 Through hole 46 Parallel link 47 Front cover 48 Driver's seat 49 Control
50 Push switch 51 Rear wheel gear case 52 Protruding part 53 Draining notch 54 Operation part 55 Main speed change lever 56 Steering handle 57 Steering motor 58 Steering sensor 59 Limit switch 60 Floor step 61 Monitor 62 Diff lock pedal 63 Seedling planting part 64 Planting device 65 units 66 Diff lock arm for pedals 67 Drive shaft 68 Transmission case 69 Planting tool 70 Planting case 71 Seedling outlet 72 Seedling tank 73 Output shaft 74 Spare seedling mounting stand 75 Float arm 76 Float shaft 77 Frame 79 Automatic running On / off switch 80 Direction sensor 82 Rear wheel axle 83 Balloon tire 85 Upper link arm 86 Lower link arm 87 Controller 88 Electro-hydraulic valve 89 Processing unit 90 Link sensor 91 RAM
92 ROM
93 Storage part 95 Implanted transmission shaft 97 Inter-share sensor 106 Number of shares sensor 110 Wave breaker 111 Protruding part 112 Wide part 113 Bending part 114 Guide 115 Cylindrical member 116 Wave generated from the vicinity of the waterline 117 Wave generated from the protruding part 118 Notch 119 Notch 120 Ultrasonic sensor 121 Cover 122 Stay 123 Cover hole 124 Bolt 125 Fixing part 126 Sensor mounting arm mounting part 127 Left / right movement restricting part 128 Left / right position determination through hole 129 Left / right position determination through hole 130 GNSS receiver 131 Sensor mounting Arm 132 Cover mounting hole 133 Front / rear positioning through hole 134 Front / rear positioning through hole 135 Insertion hole 136 Cable 137 Through hole 138 Rod-shaped member 139 Bolt 140 Nut 141 Spring 142 Pin 143 Through hole 144 Through hole 150 HST Servomotor 155 Output Shaft 156 Motor Case 157 Tooth 158 Tooth 159 Interstock Adjustment Motor Gear 160 Variable Interstock Case 161 Planetary Gear Mechanism 162 Interstock Adjustment Motor 163 Sun Gear 164 Internal Gear 165 Planetary Gear 166 Input Shaft 167 Axis 168 Planetary Carrier 169 Clutch Claw 170 Clutch Claw 171 Planting Clutch 172 Gear 173 Gear 174 Gear 175 Gear 176 Clutch Claw 177 Gear 178 Clutch Claw 179 Gear 180 Interstock Lever 181 Planting Clutch Case 182 Interstock Shift Shifter 183 Void 184 First Groove 185 Second Groove 186 Third Groove 187 Fourth groove 188 Spring 189 Ball 190 Non-constant speed switching operation tool 191 Non-uniform speed switching shifter 192 Gear 193 Input shaft 194 Gear 195 Gear position control plate 196 Output shaft 197 Gear 198 Gear 199 Non-uniform speed switching clutch 200 Field 201 One side of the field 202 One side of the field 203 One side of the field 204 One side of the field 205 First planting start position 206 Second planting start position 207 First row planting start position 210 Central area 211 Peripheral area 212 Peripheral area 213 Peripheral area 214 Peripheral area

Claims (6)

A steering device that steers the left and right running wheels,
The actuator that drives the steering device and
A differential that distributes the driving force to the left and right axles on one or both of the front and rear wheels.
Location information acquisition means to acquire vehicle location information,
An agricultural work vehicle that can run automatically and is equipped with a slip detection means that detects the slip of the running wheels located on the outside of the turn.
When the steering device is steered beyond a predetermined angle, it is determined that the aircraft is turning, and it is determined that the aircraft is turning.
An agricultural work vehicle characterized in that when the slip detection means detects slip of a traveling wheel while the machine is turning, the differential rotation of the left and right axles is limited. It is configured to be able to automatically travel on a preset automatic travel route in the field.
When turning on the automatic driving path by automatic driving, the position information of the point where the differential rotation of the left and right axles is restricted is automatically recorded in the recording device.
When automatically traveling in the same field from the next time onward, it is configured to travel on a route in which a part of the automatic traveling route is corrected so as to avoid a point where the differential rotation of the left and right axles is restricted. The agricultural work vehicle according to claim 1, wherein the work vehicle has been made. It is configured to be able to automatically travel on a preset automatic travel route in the field.
When turning on an automatic driving path by automatic driving, it is configured to allow deviation from the automatic driving path within a predetermined range while the differential rotation of the left and right axles is restricted. The agricultural work vehicle according to claim 1. When the traveling wheels slip when turning on the automatic traveling path due to automatic traveling, and the differential rotation of the left and right axles is restricted, and then the idling of the traveling wheels is eliminated, the left and right axles The agricultural work vehicle according to claim 3, wherein the differential rotation is allowed, and the vehicle is configured to return to the automatic traveling route by the shortest route. The work vehicle is configured as a seedling transplanting machine having a seedling planting portion at the rear for planting seedlings in the field.
The first inter-strain change mechanism that allows the operator to set the distance between the seedlings to be planted when the seedling transplanter moves forward in a stepwise manner.
A second inter-strain change mechanism capable of changing the inter-strain distance between seedlings in the anteroposterior direction is provided at a position behind the first inter-strain change mechanism and in front of the seedling planting portion.
The agricultural work vehicle according to any one of claims 1 to 4, wherein in the second inter-stock change mechanism, the inter-stock is changed according to the idling rate of the traveling wheel. The second inter-stock change mechanism includes a planetary gear mechanism and an actuator for inter-stock adjustment.
The planetary gear mechanism includes a sun gear that is rotated integrally with an input shaft extending from the first interstock change mechanism, a plurality of planetary gears that revolve around the sun gear, and a plurality of external teeth of the planet gear. An internal gear having meshing internal teeth and an output shaft that transmits the revolving motion of the plurality of planetary gears to the planting transmission shaft that transmits power to the seedling planting portion. Equipped with
The agricultural work according to claim 5, wherein the rotation speeds of the internal gear and the output shaft are increased or decreased by an actuator for adjusting between stocks according to the idling rate of the traveling wheel, and the stocks are changed. vehicle.

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