JP7322798B2 - work vehicle - Google Patents

Description

The present invention relates to work vehicles.

2. Description of the Related Art Conventionally, among working vehicles such as a seedling transplanter for planting seedlings in a field, for example, a working vehicle provided with a leveling member for leveling the field is known. For this type of work vehicle, there is a technique of arranging a plurality of ground leveling members in parallel along the lateral direction of the vehicle body (see, for example, Patent Document 1).

JP 2009-118846 A

However, in the conventional work vehicle, since a gap is generated between a plurality of ground leveling members, it is difficult to level the ground in such a gap, and there is a possibility that ground leveling leakage may occur.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a work vehicle capable of reducing ground leakage.

In order to solve the above-described problems and achieve the object, the work vehicle (1) according to one aspect of the embodiment includes a work machine (50), a plurality of ground leveling rotors (67a, 67b), an auxiliary rotor (67c). ). The working machine (50) is provided on the traveling vehicle body (2). The plurality of ground leveling rotors (67a, 67b) are provided in the working machine (50) and arranged in parallel along the lateral direction of the traveling vehicle body (2). The auxiliary rotor (67c) is an auxiliary rotor (67c) provided in at least one of the plurality of ground leveling rotors (67a, 67b), and the ground leveling rotors (67a, 67b) adjacent to each other in the lateral direction. They are arranged to fill the gaps between them.

According to one aspect of the embodiments, ground leakage can be reduced.

FIG. 1 is a schematic left side view showing an example of the seedling transplanter according to the embodiment. FIG. 2 is a top view of the leveling rotor. FIG. 3 is a diagram illustrating a method of avoiding interference between the auxiliary rotor and the parallel link mechanism. FIG. 4 is a diagram illustrating a method of avoiding interference between the auxiliary rotor and the parallel link mechanism. FIG. 5 is a diagram showing the peripheral configuration of the engine. FIG. 6 is a diagram showing the peripheral configuration of the engine. FIG. 7 is a diagram showing a mounting configuration of the positioning device. FIG. 8 is a diagram showing the mounting configuration of the positioning device.

Hereinafter, embodiments of a work vehicle disclosed in the present application will be described in detail with reference to the accompanying drawings. In addition, this invention is not limited by embodiment shown below. Moreover, below, a seedling transplanter is mentioned as an example and demonstrated as a working vehicle.

First, the schematic configuration of the seedling transplanter 1 will be described with reference to FIG. FIG. 1 is a schematic left side view showing an example of a seedling transplanter 1 according to an embodiment.

In the following description, the front-rear direction is the direction in which the seedling transplanter 1 moves straight, and the front side of the direction of movement is defined as "front" and the rear side is defined as "rear". The traveling direction of the seedling transplanter 1 is the direction from the later-described driver's seat 28 to the steering handle 32 when traveling straight (see FIG. 1).

The left-right direction is a lateral direction of the traveling vehicle body 2 and is a direction that is horizontally orthogonal to the front-rear direction. In the following, left and right are defined with respect to the "front" side. That is, when an operator (also referred to as an operator) is seated in the operator's seat 28 and faces forward, the left hand side is "left" and the right hand side is "right".

The vertical direction is the vertical direction. The front-back direction, the left-right direction, and the up-down direction are orthogonal to each other. These directions are defined for convenience of explanation, and the present invention is not limited by these directions. Moreover, below, the seedling transplanter 1 may be referred to as a "body".

In the following, the aircraft is referred to as "front" when viewed from the front, "back" when viewed from the rear, "plane (top)" when viewed from above, and "bottom" when viewed from below. , the case of viewing from the left side is referred to as the "left side", and the case of viewing from the right side is referred to as the "right side".

The seedling transplanter 1 plants seedlings on the topsoil surface (field surface) of the field while traveling in the field. As shown in FIG. 1 , the seedling transplanter 1 includes a traveling vehicle body 2, a seedling planting section elevating mechanism 40, and a seedling planting section 50 (an example of a working machine). The traveling vehicle body 2 includes a pair of left and right front wheels 4 and rear wheels 5 . The traveling vehicle body 2 is four-wheel drive in which each wheel (a pair of left and right front wheels 4 and a pair of left and right rear wheels 5) is driven during travel.

The traveling vehicle body 2 includes a main frame 7 , an engine 10 and a power transmission device 15 . The main frame 7 is provided at the center of the traveling vehicle body 2 in the vertical and horizontal directions, and supports the upper portion of the traveling vehicle body 2 . The engine 10 is mounted on the mainframe 7 . Engine 10 is a heat engine such as a diesel engine or a gasoline engine. The driving force from the engine 10 is used to move the traveling vehicle body 2 forward and backward, and is also used to drive a seedling planting section 50 which will be described later.

The engine 10 is provided in the center portion of the traveling vehicle body 2 in the left-right direction, and is provided in a state of protruding upward from a floor step 26 on which a worker puts his/her feet when getting on the vehicle. Note that the floor step 26 is attached to the main frame 7 and is partially formed in a lattice shape, so that mud and the like attached to the worker's shoes can be dropped onto the field. A rear step 27 that also serves as a fender for the rear wheel 5 is provided behind the floor step 26 .

An engine cover 11 that covers the engine 10 is provided on the floor step 26 and the rear step 27 . A cockpit 28 is provided above the engine cover 11 . A control section 30 is provided in front of the cockpit 28 . A front cover 31 is provided on the front portion of the control section 30 . Various operation levers, gauges, and a handle 32 for steering are provided on the upper portion of the control section 30 .

Further, the operating levers include a travel lever 35 and a sub-transmission lever 38 . The traveling lever 35 is operated to move the traveling vehicle body 2 forward and backward and to change the traveling speed. Further, the sub-transmission lever 38 is operated to switch the traveling speed of the traveling vehicle body 2 to a speed corresponding to the traveling location (field or road).

Spare seedling mounting tables 65 are provided on the left and right sides of the front portion of the floor step 26 . The spare seedling mounting table 65 is a table on which replenishment seedlings are placed, and is rotatably supported by a support shaft protruding from the step surface of the floor step 26 . The preliminary seedling mounting table 65 can be rotated manually by the operator, or can be rotated by a drive unit such as an electric motor.

The power transmission device 15 includes a hydraulic continuously variable transmission 16 and a belt-type power transmission mechanism 17 . The hydraulic continuously variable transmission 16 is a main transmission and is a hydrostatic continuously variable transmission (HST). The belt-type power transmission mechanism 17 transmits power from the engine 10 to the hydraulic continuously variable transmission 16 . The belt-type power transmission mechanism 17 includes a belt and pulleys, and transmits power from the engine 10 to the hydraulic continuously variable transmission 16 via the belt.

The power transmission device 15 also includes a transmission case 18 . Power from the engine 10 is transmitted to the mission case 18 via a belt-type power transmission mechanism 17 and a hydraulic continuously variable transmission 16 . The mission case 18 is attached to the front portion of the main frame 7 . The mission case 18 has an auxiliary transmission mechanism. The sub-transmission mechanism switches the traveling speed and the working speed when the traveling vehicle body 2 travels on the road or during planting.

The transmission case 18 divides the power changed by the sub-transmission mechanism into driving power and driving power for the seedling planting section 50 . A portion of the driving power can be transmitted to the front wheels 4 via the left and right final cases 21 and the rest can be transmitted to the rear wheels 5 via the left and right rear wheel gear cases 22 . The rear wheel gear case 22 is also connected to the ground leveling rotor 67 and transmits part of the driving power to the ground leveling rotor 67 . On the other hand, the driving power is transmitted to the planting clutch provided at the rear portion of the traveling vehicle body 2, and is transmitted to the seedling planting section 50 by the planting transmission shaft when the power is connected by the planting clutch.

The seedling planting part lifting mechanism 40 lifts the seedling planting part 50 . The seedling planting part elevating mechanism 40 includes an elevating link device 41 . The lifting link device 41 includes a parallel link mechanism 42 . The parallel link mechanism 42 includes an upper link and a lower link, and each link is rotatably connected to the link base frame 43, so that the seedling planting section 50 can be raised and lowered with respect to the traveling vehicle body 2. Link.

Moreover, the seedling planting part elevating mechanism 40 includes an elevating cylinder 44 . The elevating cylinder 44 expands and contracts by hydraulic pressure. The seedling planting part elevating mechanism 40 raises the seedling planting part 50 to the non-working position by raising and lowering the seedling planting part 50 by extending and contracting the elevating cylinder 44 . In addition, the seedling planting unit elevating mechanism 40 lowers the seedling planting unit 50 to the ground work position (planting position) by the elevating operation of the seedling planting unit 50 by the elevating cylinder 44 .

The seedling planting unit 50 is an example of a working machine, and includes a seedling mounting table 51 , a seedling planting device 60 and a float 47 . The seedling mounting table 51 has a seedling mounting surface (not shown). The seedling placement surface is partitioned in the left-right direction and provided for the number of planting rows. Mat-like seedlings with soil are loaded on each of the seedling placement surfaces. One seedling planting device 60 is provided for every two rows. The seedling planting device 60 includes a planting rod 61 , a rotary case 63 and a planting transmission case 64 .

The planting rod 61 plants the seedlings loaded on the seedling mounting table 51 in the field. The rotary case 63 is rotatably attached to a planting transmission case 64 that transmits power to the seedling planting device 60 . The planting transmission case 64 transmits the power transmitted from the engine 10 to the seedling planting unit 50 to the seedling planting device 60 .

The float 47 slides on the agricultural field as the traveling vehicle body 2 advances to level the agricultural field. The float 47 includes a center float 48 (see FIG. 2) and side floats 49 (see FIG. 2). The center float is provided at the central portion in the left-right direction, and the side floats 49 are provided at both left and right sides in the left-right direction. In front of the float 47, a leveling rotor 67, which is provided in the seedling planting section 50 and similarly levels the field, is arranged. Details of the leveling rotor 67 will be described later.

Line markers 68 are provided on both left and right sides of the seedling planting section 50 . The line marker 68 forms a line for the next planting row on the field as a reference for the direction of movement. The drawing markers 68 are driven to advance and retreat by, for example, a marker motor, and the left and right drawing markers 68 are switched each time the traveling vehicle body 2 turns.

The seedling transplanter 1 also includes a fertilizing device 70 . The fertilizing device 70 is provided at the rear of the traveling vehicle body 2 behind the operator's seat 28 . The fertilizing device 70 includes a fertilizer hopper 71 , a delivery device 72 , a fertilizing hose 74 and a blower 73 . The fertilizer hopper 71 stores fertilizer. The delivery device 72 delivers the fertilizer supplied from the fertilizer hopper 71 by a set amount. The fertilizing hose 74 is a channel for the fertilizer delivered by the delivery device 72 . A blower 73 forces air into the fertilizing hose 74 to transfer the fertilizer.

The fertilizing device 70 also includes a fertilizing guide 75 and a grooving device 76 . The fertilizing guide 75 is provided below the seedling planting section 50 and guides the fertilizing hose 74 . The grooving device 76 is provided in front of the fertilization guide 75 . The grooving device 76 forms (generates) a fertilizing ditch in the field and drops the fertilizer transferred by the fertilizing hose 74 into the fertilizing ditch.

The seedling transplanter 1 also includes a chemical spraying device 80 . The chemical spraying device 80 is arranged behind the traveling vehicle body 2 and sprays a granular chemical such as a herbicide toward the field.

Next, the leveling rotor 67 will be described in detail with reference to FIG. FIG. 2 is a top view of the leveling rotor 67. As shown in FIG.

As shown in FIG. 2 , a plurality of ground leveling rotors 67 are provided and arranged in parallel along the left-right direction of the traveling vehicle body 2 . Specifically, the ground leveling rotor 67 includes a first ground leveling rotor 67a arranged in the center in the left-right direction of the traveling vehicle body 2, and second ground leveling rotors 67a arranged at both ends of the first ground leveling rotor 67a in the left-right direction. and a leveling rotor 67b.

Further, the first ground leveling rotor 67a and the second ground leveling rotor 67b are arranged to be shifted in the longitudinal direction of the traveling vehicle body 2 . Specifically, the first grading rotor 67a is arranged forward, and the second grading rotor 67b is arranged rearward.

The first ground leveling rotor 67a and the second ground leveling rotor 67b are connected to each other via a chain case 69, which is a power transmission section. Also, of the two second ground leveling rotors 67 b , the left second ground leveling rotor 67 b is connected to the rear wheel gear case 22 via the connecting portion 66 . The second ground leveling rotor 67 b on the left side is driven by power input from the rear wheel gear case 22 . The first ground leveling rotor 67a and the right second ground leveling rotor 67b are driven by power transmitted from the left second ground leveling rotor 67b via the chain case 69 .

An auxiliary rotor 67c is arranged between the first ground leveling rotor 67a and the second ground leveling rotor 67b in the lateral direction of the traveling vehicle body 2 . Specifically, the auxiliary rotor 67c is provided at the right end of the left second ground leveling rotor 67b and the left end of the right second ground leveling rotor 67b.

More specifically, the auxiliary rotor 67c is a part of the second ground leveling rotor 67b, and is arranged at a position that sandwiches (the connection portion of) the chain case 69 with the second ground leveling rotor 67b.

Note that the auxiliary rotor 67c may be provided only on either the left second ground leveling rotor 67b or the right second ground leveling rotor 67b, or alternatively, of the two ends of the first ground leveling rotor 67a, Either or both may be provided.

That is, the auxiliary rotor 67c is provided in at least one of the plurality of ground leveling rotors 67, and the gap between the ground leveling rotors (the first ground leveling rotor 67a and the second ground leveling rotor 67b) adjacent to each other in the left-right direction of the traveling vehicle body 2 is defined. are arranged to fill the

The auxiliary rotor 67c can level the ground between the plurality of ground leveling rotors. That is, according to the seedling transplanter 1 according to the embodiment, ground leveling leakage can be reduced.

Further, as shown in FIG. 2, the auxiliary rotor 67c is arranged so as to partially overlap the first leveling rotor 67a in the left-right direction. Specifically, the end of the auxiliary rotor 67c provided in the second ground leveling rotor 67b on the left side is located to the right of the left end (chain line La) of the first ground leveling rotor 67a. In addition, the end of the auxiliary rotor 67c provided on the second ground leveling rotor 67b on the right side is located to the left of the right end (chain line Lb) of the first ground leveling rotor 67a. As a result, ground leveling leakage in the gap between the first ground leveling rotor 67a and the second ground leveling rotor 67b can be eliminated.

Although FIG. 2 shows the case where the auxiliary rotor 67c is a part of the second ground leveling rotor 67b, the auxiliary rotor 67c is configured as a separate member from the second ground leveling rotor 67b and can be attached to and detached from the second ground leveling rotor 67b. It may be attached as possible.

Further, as shown in FIG. 2, a plurality of floats 47 (ground leveling floats) including a center float 48 and side floats 49 are provided behind the first leveling rotor 67a and the second leveling rotor 67b.

The center float 48 and the side floats 49 are arranged side by side along the left-right direction of the traveling vehicle body 2 . Specifically, the center float 48 is arranged at the center in the left-right direction, and the side floats 49 are arranged at both ends of the center float 48 in the left-right direction.

A leveling member 46 is arranged between the center float 48 and the side floats 49 . Specifically, a leveling member 46 is arranged at each end of the center float 48 .

In other words, the center float 48 is arranged behind the first grading rotor 67a, the side float 49 is arranged behind the second grading rotor 67b, and the grading member 46 is arranged behind the auxiliary rotor 67c. be done.

Since the ground leveling member 46 can level the ground between the center float 48 and the side floats 49, ground leveling leakage can be reduced.

Next, a method for avoiding interference between the auxiliary rotor 67c and the parallel link mechanism 42 will be described with reference to FIGS. 3 and 4. FIG. 3 and 4 are diagrams illustrating a method of avoiding interference between the auxiliary rotor 67c and the parallel link mechanism 42. FIG.

In FIG. 3, the state which raised the seedling planting part 50 is shown. As shown in FIG. 3, when the seedling planting section 50 is raised, the auxiliary rotor 67c and the parallel link mechanism 42 interfere with each other. In order to avoid this interference, as shown in FIG.

A lifting operation unit 100 shown in FIG. 4 is an operation member operated when a worker or the like raises or lowers the seedling planting unit 50 . Specifically, when raising the seedling planting part 50 , the raising/lowering lever 110 is engaged with the engagement groove 101 . The lifting lever 110 is connected to a connecting portion 120 that is connected to the parallel link mechanism 42 , and when the lifting lever 110 is engaged with the engaging groove 101 , the seedling planting portion 50 moves through the connecting portion 120 . to rise. Further, the lifting lever 110 is regulated from moving toward the height adjusting groove 102 by being pulled by the spring 130 .

In addition, the elevation operation unit 100 has a height adjustment groove 102, and by engaging the elevation lever 110 with one of the height adjustment grooves 102, the seedling planting unit 50 can be raised to a height corresponding to the groove. down to

By securing the width of the engagement groove 101 by a predetermined length, the lifting lever 110 can have a margin in the engagement groove 101 . In other words, even if the lift lever 110 is pressed from the connecting portion 120 by the interference between the auxiliary rotor 67c and the parallel link mechanism 42, the width of the engagement groove 101 can absorb the pressure.

Next, the configuration around the engine 10 will be specifically described with reference to FIGS. 5 and 6. FIG. 5 and 6 are diagrams showing the peripheral configuration of the engine 10. FIG. As shown in FIG. 5 , the engine 10 is provided with an alternator 220 , and a cooling fan 300 for discharging the heat of the engine 10 is provided at the pulley portion of the alternator 200 .

An exhaust pipe 400 connected to the engine 10 passes above the alternator 200 . As shown in FIG. 5 , covers 420 are provided above and to the sides of the exhaust pipe 400 . The cover 420 can suppress the heat of the exhaust pipe 400 from spreading upward and laterally.

Furthermore, a wind direction plate 421 connected to the cover 420 is provided below the exhaust pipe 400 . The wind direction plate 421 is arranged facing the cooling fan 300 . In other words, wind direction plate 421 is arranged to release the heat of exhaust pipe 400 toward cooling fan 300 .

As a result, the heat of the exhaust pipe 400 can be prevented from flowing to the alternator 200, and the cooling fan 300 can enhance the heat exhaust effect, so that the surface temperature and ambient temperature of the alternator 200 can be lowered.

Further, as shown in FIG. 6, since the frame, which is the traveling vehicle body 2, is arranged in front of the cooling fan 300, if hot air discharged from the cooling fan 300 hits the traveling vehicle body 2, There is a risk that it will return to the engine 10 side.

Therefore, as shown in FIG. 6, by providing a wind direction plate 500 between the cooling fan 300 and the traveling vehicle body 2, the air discharged from the cooling fan 300 does not hit the traveling vehicle body 2 but hits the wind direction plate 500 and is discharged to the outside. be done. Thereby, the temperature rise of the engine 10 can be suppressed.

Although not shown in FIG. 5, by providing a wind direction plate separately between the crank pulley 600 and the exhaust pipe 400 (or muffler not shown), the ambient temperature of the belt 700 connected to the crank pulley 600 can be lowered.

An engine cover is arranged above the engine 10 together with an air cleaner (not shown). For this reason, the heat of the engine 10 stays in the engine cover, and there is a risk that the heat applied to the air cleaner will be sucked.

Therefore, a cover is provided to cover the engine cover side of the intake port of the air cleaner. As a result, it is possible to prevent the heat that has accumulated in the engine cover from being taken in.

Next, the mounting configuration of the positioning device 800 will be described with reference to FIGS. 7 and 8. FIG. 7 and 8 are diagrams showing the mounting configuration of the positioning device 800. FIG. As shown in FIGS. 7 and 8, the seedling transplanter 1 may further include a positioning device 800. FIG. The positioning device 800 is, for example, a GNSS (Global Navigation Satellite System), and can perform positioning and timekeeping by receiving radio waves from navigation satellites orbiting in the sky. Based on the positioning information obtained by the positioning device 800, the seedling transplanter 1 realizes automatic control of field work.

As shown in FIG. 7 , the positioning device 800 is supported above the front cover 3 by a first support portion 810 . The first support portion 810 extends from the front to the lower side of the front cover 31 and is fixed to the traveling vehicle body 2 below the front cover 31 .

A second support portion 820 is fixed to the front cover 31 to support a display portion 830 that displays various information. Specifically, the second support portion 820 supports the display portion 830 above the front cover 31 . The display unit 830 displays information such as the steering assistance state and the reception status of the positioning device 800 . Further, the second support portion 820 routes the harness of the display portion 830 inside.

Furthermore, the second support portion 820 supports the first support portion 810 . As a result, the rigidity of the first support portion 810 can be increased, and the stability can be increased.

Further, as shown in FIG. 8 , the first support portion 810 is configured to be splittable in the horizontal direction of the traveling vehicle body 2 .

In addition, the seedling transplanter 1 may be provided with an electric fan for cooling the engine above the engine cover. The seedling transplanter 1 may have a radiator in front of the engine 10 .

At this time, the seedling transplanter 1 reverses the radiator fan. As a result, outside air is taken in from behind the engine 10 and hits the engine 10 through the radiator. In such a case, a lid is arranged to block the duct in front of the engine cover.

Next, control of the seedling transplanter 1 will be described.

The seedling transplanter 1 is controlled by a control device (not shown). The control device includes an ECU (Electronic Control Unit) that controls various functions of the seedling transplanter 1 .

When the seedling planting unit 50 rises, the control device increases the engine speed to increase the speed of the rise. Further, the control device may operate the lever of the hydraulic continuously variable transmission 16 to increase the engine speed when the seedling planting section 50 is raised, thereby increasing the rate of elevation.

Further, the control device can increase the engine speed by operating the accelerator motor. Moreover, a control apparatus will stop raising engine rotation speed, if raise of the seedling planting part 50 is completed (uppermost state).

Further, the controller can detect the lift height of the seedling planting part 50 by providing a potentiometer in the seedling planting part lifting mechanism 40 .

Also, during turning, when the machine body comes to the turning position, the control device once turns the steering wheel in the direction opposite to the turning direction, and then turns around to start the next planting. This allows smooth turning.

Further, the control device controls to increase the speed of the rear wheel on the outer side of the turn during turning. This allows smooth turning.

Further, the control device controls to return the steering wheel once and turn the steering wheel again when turning. This allows smooth turning.

Furthermore, the control device controls the steering wheel to make a wide turn without turning the steering wheel all the way when turning. This allows smooth turning.

The control device also counts the number of seedlings placed in the seedling tank and the number of empty boxes placed in the empty box recovery device. First, the control device calculates the number of seedlings to be used in the first process. Subsequently, the control device controls to turn when the second stroke can go without replenishing seedlings, and to approach the ridge when it cannot go.

The control device also calculates the amount of water put in the water tank of the wash water and the amount of water used in the first process. In addition, the control device controls to turn when the second stroke can go without replenishing water, and to approach the ridge when it cannot go.

The control device also calculates the amount of fertilizer used in the first stroke. In addition, the control device controls to turn when the second stroke can be done without replenishing fertilizer, and to approach the ridge when it cannot be done.

Also, the control device controls to record and reproduce the trunnion opening. In addition, the control device records the opening of the trunnion when the button for recording the opening of the trunnion is pressed during planting work.

A button for recording the trunnion opening degree is arranged on the grip portion of the lever of the hydraulic continuously variable transmission 16 . The controller also records the position of the trunnion arm and the position of the motor and lever of the hydraulic continuously variable transmission 16 at that time when such a button is pressed. The position of the trunnion arm and the positions of the motor and lever of the hydraulic continuously variable transmission 16 are read by a potentiosensor.

Also, when the button is pressed, the control device records the position information measured by the positioning device 800 . Based on the position information, the control device automatically performs, for example, turning at the four corners of the field. Specifically, the control device acquires GPS position information and automatically turns the rice transplanter by pressing the square turn button while the rice transplanter is advanced to the edge of the ridge and stopped.

In addition, when the lever of the hydraulic continuously variable transmission 16 is pushed backward, the control device controls the seedling transplanter 1 to move backward up to a certain distance. This fixed distance is the distance until the output pulse of the rotation sensor for the rear wheel becomes a specified pulse. In addition, the control device automatically stops the vehicle when it moves backward to a certain distance.

Further, the control device controls the seedling transplanter 1 to move forward up to a certain distance when the lever of the hydraulic continuously variable transmission 16 is pushed forward. Further, the control device starts turning control when the seedling transplanter 1 comes to a predetermined position. The predetermined position is calculated by the distance until the output pulse of the rotation sensor for the rear wheels reaches the specified pulse.

As described above, the work vehicle (seedling transplanter 1) according to the embodiment includes a work machine (seedling planting unit 50), a plurality of leveling rotors 67a and 67b, and an auxiliary rotor 67c. The working machine is provided on the traveling vehicle body 2 . A plurality of ground leveling rotors 67 a and 67 b are provided on the work machine and arranged side by side along the traveling vehicle body 2 . The auxiliary rotor 67c is provided in at least one of the plurality of ground leveling rotors 67a and 67b, and is arranged so as to fill the gap between the ground leveling rotors 67a and 67b adjacent to each other in the lateral direction. Thereby, leveling leakage can be reduced.

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

1 seedling transplanter 2 traveling vehicle body 3 front cover 4 front wheel 5 rear wheel 7 main frame 10 engine 11 engine cover 15 power transmission device 16 hydraulic continuously variable transmission 17 belt type power transmission mechanism 18 mission case 21 final case 22 rear wheel gear Case 26 Floor step 27 Rear step 28 Cockpit seat 30 Control unit 31 Front cover 32 Handle 35 Travel lever 38 Auxiliary transmission lever 40 Seedling planting section elevating mechanism 41 Elevating link device 42 Parallel link mechanism 43 Link base frame 44 Elevating cylinder 46 Leveling member 47 Float 48 Center float 49 Side float 50 Seedling planting unit 51 Seedling mounting table 60 Seedling planting device 61 Planting rod 63 Rotary case 64 Planting transmission case 65 Spare seedling mounting table 66 Connecting parts 67, 67a, 67b Leveling rotor 67c Auxiliary rotor 68 Drawing marker 69 Chain case 70 Fertilizing device 71 Fertilizer hopper 72 Delivery device 73 Blower 74 Fertilizing hose 75 Fertilizing guide 76 Grooving device 80 Chemical spraying device 100 Lifting operation unit 101 Engaging groove 102 Height adjusting groove 110 Lifting lever 120 connecting part 130 spring 200 alternator 220 alternator 300 cooling fan 400 exhaust pipe 420 cover 421 wind direction plate 500 wind direction plate 600 crank pulley 700 belt 800 positioning device 810 first support portion 820 second support portion 830 display portion

Claims (3)

a work machine provided on a traveling vehicle body;
a plurality of ground leveling rotors provided in the working machine and arranged in parallel along the lateral direction of the traveling vehicle body;
an auxiliary rotor provided in at least one of the plurality of ground leveling rotors, the auxiliary rotor being arranged to fill a gap between the ground leveling rotors adjacent to each other in the lateral direction;
a plurality of ground leveling floats arranged in parallel along the lateral direction behind the plurality of ground leveling rotors;
a ground leveling member arranged to fill a gap between the ground leveling floats adjacent to each other in the lateral direction;
with
The plurality of ground leveling rotors are
comprising a first ground leveling rotor and a second ground leveling rotor that are displaced in the longitudinal direction of the traveling vehicle body;
The first leveling rotor is
arranged forward in the front-rear direction and centrally in the lateral direction;
The second ground leveling rotor is
disposed at the rear in the front-rear direction and at both ends of the first ground leveling rotor in the lateral direction;
The auxiliary rotor is
is arranged only on the second ground leveling rotor and is arranged to partially overlap the first ground leveling rotor in the lateral direction ;
The plurality of leveling floats are
A center float disposed behind the first ground leveling rotor and sandwiched between the two second ground leveling rotors, and 2 located behind each of the two second ground leveling rotors. with two side floats,
The center float is
A portion behind the auxiliary rotor protrudes laterally, so that it has a projecting shape that enters behind the auxiliary rotor,
The ground leveling member is
Arranged rearward of the auxiliary rotor and rearward of the projecting shape, and arranged so as to partially overlap the auxiliary rotor and the projecting shape in the front-rear direction.
A work vehicle characterized by: further comprising a power transmission unit connecting an end of the first ground leveling rotor and an end of the second ground leveling rotor;
The auxiliary rotor is
The work vehicle according to claim 1, wherein the work vehicle is arranged at a position sandwiching the power transmission section between the second ground leveling rotor and the second ground leveling rotor. It also has a gear case that transmits the power of the engine to the rear wheels,
The plurality of ground leveling rotors are
The work vehicle according to claim 2, wherein the work vehicle is connected to the gear case and driven by power input from the gear case.

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