JP2021185778A - Combine harvester - Google Patents

Abstract

To provide a combine harvester capable of efficiently switching between a waste straw conveyance guide body and a waste straw cutter by forming a large space behind a thresher and a grain tank.SOLUTION: A waste straw conveyance guide body for discharging waste straw grain culms conveyed by a waste straw conveyance device of a thresher 4 to the outside is provided at a rear side of the thresher 4, and a waste straw cutter for shredding waste straw grain culms and carrying to the outside is provided below the waste straw conveyance guide body. A discharge switching device 40 for switching the operation state of the waste straw conveyance guide body and the waste straw cutter is provided in the right wall of the thresher 4, and in a right side view, the discharge switching device 40 is provided at a front side from a cutting treatment chamber 17 internally equipped with the waste straw cutter.SELECTED DRAWING: Figure 7

Description

The present invention relates to a combine having a straw-removing guide body for discharging straw to the outside and a straw-removing cutter behind the threshing device.

Conventionally, a switching device is used to switch between a straw transport guide body (dropper) that discharges the straw that has been threshed by the threshing device to the outside and a straw cutter that shreds the straw provided below it and discharges it to the outside. The technique of switching was known. (See Patent Document 1).

Japanese Unexamined Patent Publication No. 2007-82455

However, in the conventional configuration, since the switching device is provided overhanging to the right side of the straw cutter, the space formed behind the threshing device and the grain tank is narrowed, and the discharge device provided behind the grain tank is narrowed. There was a risk that the placement of the auger's threshing section and fuel tank would be restricted.

Therefore, an object of the present invention is to propose a combine capable of efficiently switching between a straw-removing guide body and a straw-removing cutter by forming a large space behind a threshing device or a grain tank.

The present invention that solves the above problems is as follows.
That is, in the invention according to claim 1, a traveling device (2) is provided on the lower side of the machine frame (1) on which the engine (E) is mounted, and a cutting device (3) is provided on the front side of the machine frame (1). A threshing device (4) is provided on the rear left side of the cutting device (3), a control unit (5) is provided on the rear right side of the cutting device (3), and a grain tank (5) is provided on the rear side of the control unit (5). In the combine provided with 7)
On the rear side of the threshing device (4), a straw transport guide body (16) for discharging the straw grain stalks transported by the straw transport device (15) of the threshing device (4) to the outside, and the straw transport guide body (16). A straw cutter (18) that shreds the straw grain stalk and carries it out to the outside is provided under the straw transport guide body (16), and the straw transport guide is provided on the right wall of the threshing device (4). A discharge switching device (40) for switching the operating state of the body (16) and the straw cutter (18) was provided, and the discharge switching device (40) and the straw cutter (18) were incorporated in the right side view. It is a combine characterized by being provided on the front side of the cutting processing chamber (17).

The invention according to claim 2 is claimed in which the discharge switching device (40) is provided on the rear side of a frying cylinder (51) for frishing the second product of the threshing device (4) in the right side view. It is the combine described in 1.

The invention according to claim 3 is the combine according to claim 1 or 2, wherein the discharge switching device (40) is provided with the longitudinal direction along the front-rear direction.

According to the fourth aspect of the present invention, the discharge switching device (40) is attached to a first arm (56) for connecting and disconnecting a clutch for transmitting the output rotation of the engine (E) to the straw cutter (18). A second wire (49) is attached to a first link (44) connected via a first wire (48) and a second arm (57) that rotates the straw-removing guide body (16) into a shunting posture and a guiding posture. A second link (45) connected via a), a rotating plate (43) to which the front portions of the first link (44) and the second link (45) are rotatably fixed, and the rotating plate ( 43) The invention according to any one of claims 1 to 3, wherein the motor (42) for rotating the first wire (48) is provided and the lengths of the first wire (48) and the second wire (49) are formed to have substantially the same length. It is a combine.

The invention according to claim 5 is the first wire (48) on the same radius from the rotating shaft (42A) in the rotating plate (43) in the axial view of the rotating shaft (42A) of the motor (42). The combine according to claim 4, wherein the front portion of the second wire (49) and the front portion of the second wire (49) are rotatably fixed.

The invention according to claim 6 is connected to the rotary plate (43) with a third arm (55) for connecting and disconnecting a clutch for transmitting the output rotation of the engine (E) to the grain removing device (4). The third wire (47) is rotatably fixed, and the length of the third wire (47) is formed so that the lengths of the first wire (48) and the second wire (49) are substantially the same. The combine according to claim 4 or 5.

The invention according to claim 7 is the first wire (48) on the same radius from the rotating shaft (42A) in the rotating plate (43) in the axial view of the rotating shaft (42A) of the motor (42). The combine according to claim 6, wherein the front portion of the second wire (49), the front portion of the second wire (49), and the rear portion of the third wire (47) are rotatably fixed.

According to the invention according to claim 1, the straw-removing grain transport that has been transported by the straw-discharging transport device (15) of the threshing device (4) is discharged to the outside to the rear side of the grain-removing device (4). A straw cutter (18) is provided below the guide body (16) and the straw transport guide body (16) to shred the straw grain stalks and carry them out, and on the right wall of the threshing device (4). A discharge switching device (40) for switching the operating state of the straw discharge guide body (16) and the straw discharge cutter (18) is provided, and the discharge switching device (40) is provided by the straw discharge cutter (18) in the right side view. Since it is provided in front of the internal cutting processing chamber (17), it prevents the discharge switching device (40) from extending to the right side of the cutting processing chamber (17), and the threshing device (4) and the grain tank (4). A large space can be formed on the rear side of 7).

According to the invention of claim 2, in addition to the effect of the invention of claim 1, in the right side view, the discharge switching device (40) and the threshing device (4) are used to lift the second product. Since it is provided on the rear side of the cylinder (51), the space formed behind the threshing cylinder (51) can be effectively utilized.

According to the invention of claim 3, in addition to the effect of the invention of claim 1 or 2, since the longitudinal direction of the discharge switching device (40) is provided along the front-rear direction, the frying cylinder (51) can be used. The space formed behind can be used more effectively.

According to the invention of claim 4, in addition to the effect of the invention according to any one of claims 1 to 3, the discharge switching device (40) has a straw cutter (18) and an engine (E). The first link (44) connected to the first arm (56) that connects and disconnects the clutch that transmits the output rotation via the first wire (48) and the straw-removing guide body (16) are evacuated. A second link (45) connected to a second arm (57) rotated into a posture and a guide posture via a second wire (49), and the front part of the first link (44) and the second link (45). Is provided with a rotary plate (43) rotatably fixed and a motor (42) for rotating the rotary plate (43), and the lengths of the first wire (48) and the second wire (49) are substantially the same. Since it is formed in, the motor (42) can be driven to efficiently switch between the driving of the straw-removing cutter (18) and the driving of the straw-removing guide body (16).

According to the invention of claim 5, in addition to the effect of the invention of claim 4, in the axial view of the rotating shaft (42A) of the motor (42), from the rotating shaft (42A) in the rotating plate (43). Since the front part of the first wire (48) and the front part of the second wire (49) are rotatably fixed on the same radius, the motor (42) is driven to transport the straw cutter (18) and the straw. The drive of the guide body (16) can be switched more efficiently. It is also possible to prevent the output torque of the motor (42) from becoming excessively large.

According to the invention of claim 6, in addition to the effect of the invention of claim 4 or 5, a clutch for transmitting the output rotation of the engine (E) to the grain removing device (4) is connected to the rotating plate (43). The third wire (47) connected to the third arm (55) for disconnecting from the wire is rotatably fixed, and the length of the third wire (47) is the length of the first wire (48) and the second wire (48). Since the lengths of 49) are formed to be substantially the same, the drive of the grain removal device (4) can be operated by the discharge switching device (40). Further, it is not necessary to separately provide a motor or the like for operating the third wire (47), and the number of parts can be reduced.

According to the invention of claim 7, in addition to the effect of the invention of claim 6, in the axial view of the rotary shaft (42A) of the motor (42), from the rotary shaft (42A) in the rotary plate (43). Since the front part of the first wire (48), the front part of the second wire (49), and the rear part of the third wire (47) are rotatably fixed on the same radius, the output torque of the motor (42) Can also be suppressed from becoming excessively large.

It is a plan view of a combine. It is a left side view of the combine. It is a front view of a combine. It is a rear view of a combine. It is a left side view of the rear part of a reaping device. It is a vertical sectional view in the front-rear direction of a threshing device. It is a right side view of a threshing device. It is a front view of the threshing device. It is a rear view of the threshing device. It is a top view of the discharge switching device. It is explanatory drawing of the handling body of the discharge switching device, the straw discharge cutter, and the discharge straw transport guide body stop state. It is explanatory drawing of the handling cylinder / straw cutter operating state of the discharge switching device. It is explanatory drawing of the handling cylinder, the straw discharge guide body operation state of the discharge switching device. It is a connection diagram of a controller. It is a driving method of the discharge switching device.

As shown in FIGS. 1 to 4, the combine is provided with a traveling device 2 consisting of a pair of left and right crawlers traveling on the soil surface under the machine frame 1, and the grain culm in the field is cut on the front side of the machine frame 1. A harvesting device 3 is provided, a threshing device 4 for threshing and sorting the harvested culms is provided on the rear left side of the harvesting device 3, and a control unit 5 on which the operator rides is provided on the rear right side of the harvesting device 3. ing.

An engine room 6 for mounting the engine E is provided on the lower side of the control unit 5, and a grain tank 7 for storing threshed and sorted grains is provided on the rear side of the control unit 5. A discharge auger 8 is provided on the rear side, which is composed of a threshing portion extending in the vertical direction and a lateral discharging portion extending in the front-rear direction to discharge grains to the outside.

As shown in FIGS. 5 and 6, a transport device 11 for transferring the cut culm from the cutting device 3 to the threshing device 4 is provided at the rear of the cutting device 3. The left wall of the threshing device 4 is provided with a feed chain 12 and a pinching rod 13 for transporting the transported grain culms along an opening provided in the left wall of the threshing device 4. As a result, the cut culms can be efficiently transferred from the reaping device 3 to the threshing device 4, and the transferred culms can be efficiently transported along the opening of the threshing device 4.

At the rear of the threshing device 4, a straw-removing transport device 15 for transporting the grain culms (hereinafter referred to as straw-exhausted culms) that have been threshed by the handling cylinder 14 to the rear is provided. Below the rear part of the straw transport device 15, the straw transport guide body 16 for changing the guide destination of the straw culm transferred from the straw transport device 15 and the straw transport device 15 have been transferred. A cutting processing chamber 17 is provided to shred the straw culm and discharge it to the rear of the machine, and a straw cutter 18 for shredding the straw culm is rotatably placed on the left and right walls of the cutting processing chamber 17. It is erected. As a result, the straw culm can be efficiently transferred to the straw transport guide body 16 or the cutting processing chamber 17 and efficiently discharged to the outside from the straw transport guide body 16 or the like.

As shown in FIG. 1, a front panel 20 is provided on the front side of the driver's seat 5A of the control unit 5, and a side panel 30 is provided on the left side.

A monitor 21 for displaying the traveling speed of the traveling device 2 and the like is provided in the central portion of the front panel 20, and a turning lever 22 for performing a turning operation of the machine body and the like is provided on the right side of the monitor 21. Further, the swivel angle of the swivel lever 22 is measured by a swivel sensor 22A provided at the lower part of the swivel lever 22.

A main shift lever 31 for operating the HST provided between the engine E and the transmission to accelerate or decelerate the traveling speed of the traveling device 2 is provided on the front portion of the side panel 30, and is provided on the rear side of the main shifting lever 31. Is provided with an auxiliary speed change lever 32 that operates a transmission to accelerate or decelerate the traveling speed of the traveling device 2.

On the left side of the main speed change lever 31, a rescue switch 33 for raising the cutting device 3 from the soil surface to a predetermined height and moving it to a rescue posture, and an emergency stop switch 34 for stopping the drive of the engine E when an abnormality occurs are provided. ing. Further, when the rescue switch 33 is input, the hydraulic cylinder 33A that raises and lowers the cutting device 3 is driven.

On the left side of the auxiliary speed change lever 32, a start lever 35 for activating the control motor 42 built in the discharge switching device 40, which will be described later, for switching the drive of the straw discharge guide body 16 and the straw discharge cutter 18 is provided and started. On the left side of the lever 35, a switching lever 36 for switching the drive of the straw exhausting guide body 16 and the straw exhausting cutter 18 is provided.

As shown in FIG. 7, on the right wall of the threshing device 4, a straw culm transport guide body 16 for discharging a predetermined amount of straw culm to the rear of the machine body and a straw culm cutter 18 for shredding the straw culm are shredded. The discharge switching device 40 for switching the drive of the culm is provided.

As shown in FIG. 10 and the like, the discharge switching device 40 is fixed to the motor 42 provided on the right side of the inverted L-shaped fixing plate 41 and to the rotating shaft 42A of the motor 42 on the left side of the fixing plate 41. It is formed from a rotating plate 43 having a substantially two isosceles triangle shape. Further, the rotation angle of the rotation shaft 42A is measured by an angle sensor such as a potentiometer installed on the rotation shaft 42A.

A front portion of a substantially arcuate cutter link (“first link” in claim) 44 projecting downward is connected to one side of the bottom portion of the rotating plate 43, and is connected to the other side of the bottom portion of the rotating plate 43. Is connected to a guide link (“second link” in claim) 45 having a substantially arc shape protruding upward. Further, the rear portion of the threshing wire (“third wire” in claim) 47 arranged forward is connected to the top of the rotating plate 43, and the rear portion of the cutter link 44 is directed backward. The front part of the cutter wire (“first wire” in the claim) 48 to be arranged is connected, and the guide wire (in the claim) to be arranged rearward is connected to the rear part of the guide link 45. The front portion of the "second wire") 49 is connected.

The front portion of the threshing wire 47 is connected to a threshing clutch (not shown) that transmits the output rotation of the engine E to the handling cylinder 14 and the like. When the threshing wire 47 moves rearward, the threshing clutch is connected to drive the handling cylinder 14 and the like. On the other hand, when the threshing wire 47 moves forward, the threshing clutch is disengaged and the driving of the handling cylinder 14 and the like is stopped.

The rear portion of the cutter wire 48 is connected to a cutter clutch (not shown) that transmits the output rotation of the engine E to the straw cutter 18. When the cutter wire 48 moves forward, the cutter clutch is engaged and the straw cutter 18 is driven. On the other hand, when the cutter wire 48 moves rearward, the connection of the cutter clutch is released and the driving of the straw cutter 18 is stopped.

The rear portion of the guide wire 49 is connected to the straw transport guide body 16. When the guide wire 49 moves forward, the straw discharge transport guide body 16 rotates counterclockwise in FIG. 6 around a support shaft extending in the left-right direction of the lower end portion of the straw discharge transport guide body 16. However, below the straw-removing transport device 15, the longitudinal direction is moved to a guiding posture along the extension in the front-rear direction of the machine body. That is, in this guidance posture, the straw culm transported by the straw transport device 15 is guided backward as it is, and is discharged to the outside of the machine without passing through the straw cutter 18. On the other hand, when the guide wire 49 moves backward, the straw-removing guide body 16 rotates clockwise around the support axis at the lower end portion in FIG. 6 and moves to an upright evacuation posture. In this retracted posture, the straw-removing guide body 16 is in a state where the upper part of the straw-removing cutter 18 is opened, so that the straw-grained culm transported by the straw-removing transport device 15 falls to the straw-removing cutter 18. Shredded.

As a result, one motor 42 can operate the handling cylinder 14, the straw-removing guide body 16, and the straw-removing cutter 18 to drive and stop the drive, reducing the number of parts and reducing the maintenance work load. be able to.

As shown in FIG. 7, the longitudinal direction of the discharge switching device 40 is provided along the front-rear direction of the machine body. In the right side view, the discharge switching device 40 transfers the first threshing cylinder 50 that transfers the threshed and sorted grains to the grain tank 7, and the second fried grain that transfers the second product such as the stabbed grain to the threshing device 4 again. It is provided behind the grain tube (“threshing tube” in the claim) 51 and in front of the cutting processing chamber 17. As a result, the space formed behind the first fried grain cylinder 50 and the second fried grain cylinder 51 can be effectively utilized.

Further, the discharge switching device 40 includes a grain removal wire 47 arranged forward from the discharge switching device 40, and a cutter wire 48 and a guide wire 49 arranged rearward from the discharge switching device 40. The length is the same, that is, the shortest wire length of the degraining wire 47, the cutter wire 48, and the guide wire 49 is 90% or more of the longest wire length. It is preferable to provide the wire at the above position. As a result, the force for moving the threshing wire 47 backward and the force for moving the cutter wire 48 and the guide wire 49 forward can be made substantially the same, so that a small motor 42 can be used. The discharge switching device 40 can be formed more compactly.

As shown in FIGS. 8 and 9, the threshing wire 47 extends forward through between the right wall of the threshing device 4 and the second freshing cylinder 51 and extends forward to the threshing arm of the threshing clutch ("in claim". It is connected to the "third arm") 55. The cutter wire 48 extends rearward through below the rear wall of the threshing device 4 and is provided on the left wall of the cutting processing chamber 17 as a cutter arm (“first arm” in the claim). It is connected to 56. The guide wire 49 extends to the rear through an opening formed in the rear wall of the threshing device 4 and is connected to the lower part of the support shaft to the guide arm (“second arm” in the claim) 57. It is linked.

When the start lever 35 of the side panel 30 is moved from the rear side to the front side, the start of the motor 42 of the discharge switching device 40 is started.

When the switching lever 36 of the side panel 30 is moved from the rear side to the front side, that is, when the switching lever 36 is moved from the straw transfer guide body side to the cutting cutter side, the rotating shaft 42A rotates clockwise as shown in FIG. Then, the threshing wire 47 moves rearward from the neutral position via the rotating plate 43, the cutter wire 48 moves forward from the neutral position via the rotating plate 43 and the cutter link 44, and the guide wire 49 Moves rearward from the neutral position via the rotating plate 43 and the guide link 45.

As a result, the threshing clutch is connected to drive the handling cylinder 14, and the cutter clutch is connected to drive the straw cutter 18. On the other hand, the support shaft does not rotate, and the straw-removing guide body 16 maintains a shunting posture. In this specification, this state is referred to as a handling cylinder / straw cutter operating state.

In this state, when the switching lever 36 of the side panel 30 is moved from the front side to the rear side, that is, the switching lever 36 is moved from the cutting cutter side to the straw transfer guide body side, first, as shown in FIG. 11, the rotating shaft The 42A rotates counterclockwise, the threshing wire 47 moves to the front neutral position via the rotating plate 43, and the cutter wire 48 moves to the rear neutral position via the rotating plate 43 and the cutter link 44. It moves and the guide wire 49 moves to the front neutral position via the rotating plate 43 and the guide link 45.

As a result, the threshing clutch is disconnected, the handling cylinder 14 is stopped, the cutter clutch is disconnected, the straw cutter 18 is stopped, the support shaft does not rotate, and the straw transport guide body 16 is in a shunting posture. maintain. In addition, in this specification, this state is referred to as a handling body, a straw-removing cutter, and a straw-removing transport guide body stopped state.

Next, when a predetermined time elapses, as shown in FIG. 13, the rotation shaft 42A further rotates clockwise, and the grain removal wire 47 moves rearward from the neutral position via the rotation plate 43 for the cutter. The wire 48 moves rearward from the neutral position via the rotating plate 43 and the cutter link 44, and the guide wire 49 moves forward via the rotating plate 43 and the guide link 45.

As a result, the threshing clutch is connected to drive the handling cylinder 14, the support shaft rotates counterclockwise, and the straw-removing guide body 16 moves to the guide posture. On the other hand, the disconnection of the cutter clutch is maintained and the drive stop of the straw cutter 18 is maintained. In this specification, this state is referred to as a handling cylinder / straw transport guide body operating state.

In the description of the drive of the discharge switching device 40 described above, the case where the switching lever 36 is moved from the front side to the rear side has been described, but the switching lever 36 is moved from the rear side to the front side, that is, the straw is discharged from the straw transport guide body side. When moving to the cutter side, the handling cylinder / straw transport guide body operating state shown in FIG. 13, the handling cylinder / straw cutter / straw discharge guide body stopped state shown in FIG. 12, and the handling cylinder / body shown in FIG. The state switches in order to the straw cutter operating state.

As shown in FIG. 14, the controller 25 has a built-in timer 25A. Thereby, for example, the time between the switching of the switching lever 36 and the switching of the rotation direction of the motor 42 can be measured.

On the input side of the controller 25, a swivel sensor 22A for measuring the swivel angle of the swivel lever 22, a retreat switch 33 for moving the cutting device 3 to the retreat posture, and an emergency stop switch 34 for stopping the drive of the engine E when an abnormality occurs. A start lever 35 for activating the motor 42 of the discharge switching device 40, and a switching lever 36 for switching the drive of the straw discharge guide body 16 and the discharge straw cutter 18 are connected via a predetermined input interface circuit.

On the output side of the controller 25, a monitor 21 for displaying the combine state, a hydraulic cylinder 33A for raising and lowering the cutting device 3, and a motor 42 for the discharge switching device 40 are connected via a predetermined output interface circuit.

<Driving method of discharge switching device>
As shown in FIG. 15, in step S1, the controller 25 determines whether or not the start lever 35 has moved from the rear side to the front side, and if it determines that the start lever 35 is located on the front side, The process proceeds to step S2, and if it is determined that the start lever 35 is located on the rear side, the process proceeds to step S3. Further, the position of the start lever 35 is measured by a sensor such as a potentiometer provided at the lower part of the start lever 35.

In step S2, the controller 25 activates the motor 42 and proceeds to step S4.

In step S3, the controller 25 stops the motor 42 and returns to step S1.

In step S4, the controller 25 determines whether or not the emergency stop switch 34 is input, and if it determines that the emergency stop switch 34 is input, returns to step S3 and the emergency stop switch 34 is input. If it is determined that there is no such procedure, the process proceeds to step S5. As a result, when the emergency stop switch 34 is input, the motor 42 is stopped, the handling cylinder 14 and the like are stopped, and the safety of the working environment can be enhanced.

In step S5, the controller 25 determines whether or not the save switch 33 for moving the cutting device 3 to the save posture is input, and if it is determined that the save switch 33 is not input, returns to step S3 and saves. If it is determined that the switch 33 is input, the process proceeds to step S6. Further, the input of the rescue switch 33 is restricted to be released when the motor 42 is being driven. When the traveling device 2 is traveling, the motor 42 can be stopped.

In step S6, when the controller 25 determines whether the switching lever 36 is on the front cutting cutter side or the rear straw discharging guide body side, and determines that the switching lever 36 is located on the cutting cutter side. Proceeds to step S7, and if it is determined that the switching lever 36 is located on the straw transport guide body side, the process proceeds to step S12. Further, the position of the switching lever 36 is measured by a sensor such as a potentiometer provided at the lower part of the switching lever 36.

In step S7, as shown in FIG. 12, the controller 25 rotates the rotating shaft 42A of the motor 42 clockwise to move the grain removal wire 47 backward from the neutral position, and moves the cutter wire 48 forward from the neutral position. The guide wire 49 is moved rearward from the neutral position to proceed to step S8. As a result, the threshing clutch is connected to drive the feed chain 12, the handling cylinder 14, and the straw-removing transport device 15 of the threshing device 4, and the cutter clutch is connected to drive the straw-discharging cutter 18. On the other hand, the support shaft does not rotate, the straw-removing guide body 16 maintains a retreat posture, and the straw-removing guide body 16 stops.

In step S8, the controller 25 determines whether the switching lever 36 is on the cutting cutter side on the front side or the straw discharge transport guide body side on the rear side, and determines that the switching lever 36 is located on the cutting cutter side. Return to step S7, and if it is determined that the switching lever 36 is located on the straw transport guide body side, the process proceeds to step S9.

In step S9, as shown in FIG. 11, the controller 25 rotates the rotating shaft 42A of the motor 42 in the counterclockwise direction to move the grain removal wire 47 from the rear to the neutral position, and the cutter wire 48 from the front to the neutral position. It is moved to the position, the guide wire 49 is moved from the rear to the neutral position, and the process proceeds to step S10. As a result, the connection of the threshing clutch is disengaged, the feed chain 12, the handling cylinder 14, and the straw discharging device 15 of the threshing device 4 are stopped, the connection of the cutter clutch is disengaged, the straw excretion cutter 18 is stopped, and the support shaft. Since the straw-removing guide body 16 maintains a shunting posture and the straw-removing guide body 16 stops without rotating, the straw-removing means is being switched from the straw-discharging cutter 18 to the straw-removing transport guide body 16. It is possible to prevent the straw grain slag from being clogged in the rear part of the straw transport device 15.

In step S10, the controller 25 determines whether or not the threshing clutch is disconnected and a predetermined time has elapsed, and if it is determined that the predetermined time has not elapsed, the controller 25 repeats step S10 and the predetermined time has elapsed. If it is determined, the process proceeds to step S11. Further, the predetermined time can be set on the monitor 21 at an arbitrary time, and while the predetermined time has not elapsed, the monitor 21 displays the switching state and the like. As a result, the safety of the working environment can be enhanced.

In step S11, as shown in FIG. 13, the controller 25 further rotates the rotation shaft 42A of the motor 42 in the counterclockwise direction to move the grain removal wire 47 from the neutral position to the rear, and moves the cutter wire 48 to the neutral position. The guide wire 49 is moved forward from the neutral position to return to step S1. As a result, the threshing clutch is connected, the feed chain 12, the handling cylinder 14, and the straw-removing transport device 15 of the threshing device 4 are driven, the support shaft rotates counterclockwise, and the straw-removing transport guide body 16 is in the guide posture. Move and drive. On the other hand, the disconnection of the cutter clutch is maintained and the straw cutter 18 is subsequently stopped.

In step S12, the controller 25 determines whether or not the turning lever 22 is operated to turn the aircraft, and if it determines that the aircraft is turning, the controller 25 proceeds to step S7 and the aircraft is not turning. If it is determined that the vehicle is going straight, the process proceeds to step S13. As a result, it is possible to prevent the discharged straw from being discharged from the straw discharging guide body 16 and prevent the discharged straw from being entangled with the traveling device 2. Further, whether or not the machine is turning is measured by a turning sensor 22A such as a potentiometer provided at the lower part of the turning lever 22 for the turning angle of the turning lever 22 for turning the machine. It should be noted that whether or not the aircraft is turning can be measured by a camera image mounted on the aircraft, GPS, or the like instead of the turning sensor 22A.

In step S13, as shown in FIG. 13, the controller 25 rotates the rotation shaft 42A of the motor 42 in the counterclockwise direction to move the grain removal wire 47 from the neutral position to the rear, and moves the cutter wire 48 from the neutral position. It is moved backward, and the guide wire 49 is moved forward from the neutral position to proceed to step S14. As a result, the threshing clutch is connected to drive the feed chain 12, the handling cylinder 14, and the straw-removing transport device 15 of the threshing device 4, the support shaft rotates, and the straw-removing guide body 16 moves to the guide posture and is driven. do. Further, the connection of the cutter clutch is released and the straw cutter 18 is stopped.

In step S14, the controller 25 determines whether the switching lever 36 is on the cutting cutter side on the front side or on the straw transport guide body side on the rear side, and determines that the switching lever 36 is located on the straw transport guide body side on the rear side. In that case, the process returns to step S12, and if it is determined that the switching lever 36 is located on the cutting cutter side, the process proceeds to step S15.

In step S15, as shown in FIG. 11, the controller 25 rotates the rotating shaft 42A of the motor 42 clockwise to move the threshing wire 47 from the rear to the neutral position, and the cutter wire 48 from the rear to the neutral position. , The guide wire 49 is moved from the front to the neutral position, and the process proceeds to step S16. As a result, the connection of the threshing clutch is disengaged, the feed chain 12, the handling cylinder 14, and the straw discharging device 15 of the threshing device 4 are stopped, the support shaft rotates clockwise, and the straw discharging guide body 16 is in the shunting posture. Since the cutter clutch is continuously disconnected and the straw excretion cutter 18 is stopped, the straw culm is particularly affected during the switching of the ejection means from the straw excretion transport guide body 16 to the straw excretion cutter 18. It is possible to prevent the rear part of the straw-removing transport device 15 from being clogged.

In step S16, the controller 25 determines whether or not the threshing clutch is disconnected and a predetermined time has elapsed, and if it is determined that the predetermined time has not elapsed, the controller 25 repeats step S16 and the predetermined time has elapsed. If it is determined, the process proceeds to step S17. Further, the predetermined time can be set on the monitor 21 at an arbitrary time, and while the predetermined time has not elapsed, the monitor 21 displays the switching state and the like. As a result, the safety of the working environment can be enhanced.

In step S17, as shown in FIG. 12, the controller 25 further rotates the rotation shaft 42A of the motor 42 clockwise to move the threshing wire 47 from the neutral position to the rear, and moves the cutter wire 48 from the neutral position. The guide wire 49 is moved forward and the guide wire 49 is moved backward from the neutral position to return to step S1. As a result, the threshing clutch is connected to drive the feed chain 12, the handling cylinder 14, and the straw-removing transport device 15 of the threshing device 4, and the cutter clutch is connected to drive the straw-discharging cutter 18. On the other hand, the support shaft does not rotate, the straw-removing guide body 16 maintains a retreat posture, and the straw-removing guide body 16 stops.

INDUSTRIAL APPLICABILITY The present invention can be applied to an agricultural work vehicle provided with a cutting processing chamber equipped with a straw-removing guide body and a straw-removing cutter behind the threshing device.

1 Aircraft frame 2 Traveling device 3 Cutting device 4 Threshing device 5 Control unit 7 Glen tank 15 Straw transport device 16 Straw transport guide body 17 Cutting processing chamber 18 Straw cutter 40 Discharge switching device 42 Motor 42A Rotating shaft 43 Rotating plate 44 Cutter link (1st link)
45 Guide link (second link)
47 Threshing wire (3rd wire)
48 Cutter wire (1st wire)
49 Guide wire (second wire)
51 2nd Winnowing (Winnowing)
55 Threshing arm (3rd arm)
56 Cutter arm (1st arm)
57 Guide arm (second arm)
E engine

The present invention relates to a combine having a straw-removing guide body for discharging straw to the outside and a straw-removing cutter behind the threshing device.

Conventionally, a switching device is used to switch between a straw transport guide body (dropper) that discharges the straw that has been threshed by the threshing device to the outside and a straw cutter that shreds the straw provided below it and discharges it to the outside. The technique of switching was known. (See Patent Document 1).

Japanese Unexamined Patent Publication No. 2007-82455

However, in the conventional configuration, since the switching device is provided overhanging to the right side of the straw cutter, the space formed behind the threshing device and the grain tank is narrowed, and the discharge device provided behind the grain tank is narrowed. There was a risk that the placement of the auger's threshing section and fuel tank would be restricted.

Therefore, an object of the present invention is to propose a combine capable of efficiently switching between a straw-removing guide body and a straw-removing cutter by forming a large space behind a threshing device or a grain tank.

The present invention that solves the above problems is as follows.
That is, in the invention according to claim 1, a traveling device (2) is provided on the lower side of the machine frame (1) on which the engine (E) is mounted, and a cutting device (3) is provided on the front side of the machine frame (1). A threshing device (4) is provided on the rear left side of the cutting device (3), a control unit (5) is provided on the rear right side of the cutting device (3), and a grain tank (5) is provided on the rear side of the control unit (5). In the combine provided with 7)
On the rear side of the grain removal device (4), a straw discharge transport guide body (16) for discharging the straw grain stalks transported by the straw discharge transport device (15) of the grain removal device (4) to the outside, and the straw transport guide body (16). A straw cutter (18) that shreds the straw grain stalk and carries it out to the outside is provided under the straw transport guide body (16), and the straw transport guide is provided on the right wall of the grain removal device (4). The body (16) is switched to a guiding posture in which the straw grain stalk is discharged to the outside without passing through the straw shaving cutter (18) and a standby posture in which the straw shaving grain is dropped into the straw shaving cutter (18). A discharge switching device (40) for switching between driving and stopping the driving of the straw cutter (18) is provided, and the discharge switching device (40) is cut with the straw cutter (18) incorporated in the right side view. It is a combine characterized by being provided on the front side of the processing chamber (17).

The invention according to claim 2 is claimed in which the discharge switching device (40) is provided on the rear side of a frying cylinder (51) for frishing the second product of the threshing device (4) in the right side view. It is the combine described in 1.

The invention according to claim 3 is the combine according to claim 1 or 2 , wherein the fixing plate (41) to which the discharge switching device (40) is fixed is provided along the longitudinal direction in the front-rear direction.

According to the fourth aspect of the present invention, the discharge switching device (40) is attached to a first arm (56) for connecting and disconnecting a clutch for transmitting the output rotation of the engine (E) to the straw cutter (18). A second wire (49) is attached to a first link (44) connected via a first wire (48) and a second arm (57) that rotates the straw-removing guide body (16) into a shunting posture and a guiding posture. A second link (45) connected via a), a rotating plate (43) to which the front portions of the first link (44) and the second link (45) are rotatably fixed, and the rotating plate ( 43) The invention according to any one of claims 1 to 3, wherein the motor (42) for rotating the first wire (48) is provided and the lengths of the first wire (48) and the second wire (49) are formed to have substantially the same length. It is a combine.

The invention according to claim 5 is the first wire (48) on the same radius from the rotating shaft (42A) in the rotating plate (43) in the axial view of the rotating shaft (42A) of the motor (42). The combine according to claim 4, wherein the front portion of the second wire (49) and the front portion of the second wire (49) are rotatably fixed.

The invention according to claim 6 is connected to the rotary plate (43) with a third arm (55) for connecting and disconnecting a clutch for transmitting the output rotation of the engine (E) to the grain removing device (4). The third wire (47) is rotatably fixed, and the length of the third wire (47) is formed so that the lengths of the first wire (48) and the second wire (49) are substantially the same. The combine according to claim 4 or 5.

The invention according to claim 7 is the first wire (48) on the same radius from the rotating shaft (42A) in the rotating plate (43) in the axial view of the rotating shaft (42A) of the motor (42). The combine according to claim 6, wherein the front portion of the second wire (49), the front portion of the second wire (49), and the rear portion of the third wire (47) are rotatably fixed.

According to the invention according to claim 1, the straw-removing grain transport that has been transported by the straw-discharging transport device (15) of the grain-removing device (4) is discharged to the outside on the rear side of the grain-removing device (4). A straw cutter (18) is provided below the guide body (16) and the straw transport guide body (16) to shred the straw grain stalks and carry them out, and on the right wall of the grain removal device (4). , A guide posture in which the straw transport guide body (16) is discharged to the outside without passing through the straw cutter (18) and a standby posture in which the straw grain is dropped onto the straw cutter (18). A discharge switching device (40) for switching between driving and stopping the drive is provided, and the discharge switching device (40) is installed in the straw cutter (18) when viewed from the right side. Since it is provided in front of the cut processing chamber (17), the discharge switching device (40) is prevented from extending to the right side of the cutting processing chamber (17), and the grain removal device (4) and the grain tank (7) are prevented. ) Can form a large space behind.

According to the invention of claim 2, in addition to the effect of the invention of claim 1, in the right side view, the discharge switching device (40) and the threshing device (4) are used to lift the second product. Since it is provided on the rear side of the cylinder (51), the space formed behind the threshing cylinder (51) can be effectively utilized.

According to the invention of claim 3, in addition to the effect of the invention of claim 1 or 2 , the longitudinal direction of the fixing plate (41) to which the discharge switching device (40) is fixed is provided along the front-rear direction. , The space formed behind the frying cylinder (51) can be utilized more effectively.

According to the invention of claim 4, in addition to the effect of the invention according to any one of claims 1 to 3, the discharge switching device (40) has a straw cutter (18) and an engine (E). The first link (44) connected to the first arm (56) that connects and disconnects the clutch that transmits the output rotation via the first wire (48) and the straw-removing guide body (16) are evacuated. A second link (45) connected to a second arm (57) rotated to a posture and a guide posture via a second wire (49), and the front part of the first link (44) and the second link (45). Is provided with a rotary plate (43) rotatably fixed and a motor (42) for rotating the rotary plate (43), and the lengths of the first wire (48) and the second wire (49) are substantially the same. Since it is formed in, the motor (42) can be driven to efficiently switch between the driving of the straw-removing cutter (18) and the driving of the straw-removing guide body (16).

According to the invention of claim 5, in addition to the effect of the invention of claim 4, in the axial view of the rotating shaft (42A) of the motor (42), from the rotating shaft (42A) in the rotating plate (43). Since the front part of the first wire (48) and the front part of the second wire (49) are rotatably fixed on the same radius, the motor (42) is driven to transport the straw cutter (18) and the straw. The drive of the guide body (16) can be switched more efficiently. It is also possible to prevent the output torque of the motor (42) from becoming excessively large.

According to the invention of claim 6, in addition to the effect of the invention of claim 4 or 5, a clutch for transmitting the output rotation of the engine (E) to the grain removing device (4) is connected to the rotating plate (43). The third wire (47) connected to the third arm (55) for disconnecting from the wire is rotatably fixed, and the length of the third wire (47) is the length of the first wire (48) and the second wire (48). Since the lengths of 49) are formed to be substantially the same, the drive of the grain removal device (4) can be operated by the discharge switching device (40). Further, it is not necessary to separately provide a motor or the like for operating the third wire (47), and the number of parts can be reduced.

According to the invention of claim 7, in addition to the effect of the invention of claim 6, in the axial view of the rotary shaft (42A) of the motor (42), from the rotary shaft (42A) in the rotary plate (43). Since the front part of the first wire (48), the front part of the second wire (49), and the rear part of the third wire (47) are rotatably fixed on the same radius, the output torque of the motor (42) Can also be suppressed from becoming excessively large.

It is a plan view of a combine. It is a left side view of the combine. It is a front view of a combine. It is a rear view of a combine. It is a left side view of the rear part of a reaping device. It is a vertical sectional view in the front-rear direction of a threshing device. It is a right side view of a threshing device. It is a front view of the threshing device. It is a rear view of the threshing device. It is a top view of the discharge switching device. It is explanatory drawing of the handling body of the discharge switching device, the straw discharge cutter, and the discharge straw transport guide body stop state. It is explanatory drawing of the handling cylinder / straw cutter operating state of the discharge switching device. It is explanatory drawing of the handling cylinder, the straw discharge guide body operation state of the discharge switching device. It is a connection diagram of a controller. It is a driving method of the discharge switching device.

As shown in FIGS. 1 to 4, the combine is provided with a traveling device 2 consisting of a pair of left and right crawlers traveling on the soil surface under the machine frame 1, and the grain culm in the field is cut on the front side of the machine frame 1. A harvesting device 3 is provided, a threshing device 4 for threshing and sorting the harvested culms is provided on the rear left side of the harvesting device 3, and a control unit 5 on which the operator rides is provided on the rear right side of the harvesting device 3. ing.

An engine room 6 for mounting the engine E is provided on the lower side of the control unit 5, and a grain tank 7 for storing threshed and sorted grains is provided on the rear side of the control unit 5. A discharge auger 8 is provided on the rear side, which is composed of a threshing portion extending in the vertical direction and a lateral discharging portion extending in the front-rear direction to discharge grains to the outside.

As shown in FIGS. 5 and 6, a transport device 11 for transferring the cut culm from the cutting device 3 to the threshing device 4 is provided at the rear of the cutting device 3. The left wall of the threshing device 4 is provided with a feed chain 12 and a pinching rod 13 for transporting the transported grain culms along an opening provided in the left wall of the threshing device 4. As a result, the cut culms can be efficiently transferred from the reaping device 3 to the threshing device 4, and the transferred culms can be efficiently transported along the opening of the threshing device 4.

At the rear of the threshing device 4, a straw-removing transport device 15 for transporting the grain culms (hereinafter referred to as straw-exhausted culms) that have been threshed by the handling cylinder 14 to the rear is provided. Below the rear part of the straw transport device 15, the straw transport guide body 16 for changing the guide destination of the straw culm transferred from the straw transport device 15 and the straw transport device 15 have been transferred. A cutting processing chamber 17 is provided to shred the straw culm and discharge it to the rear of the machine, and a straw cutter 18 for shredding the straw culm is rotatably placed on the left and right walls of the cutting processing chamber 17. It is erected. As a result, the straw culm can be efficiently transferred to the straw transport guide body 16 or the cutting processing chamber 17 and efficiently discharged to the outside from the straw transport guide body 16 or the like.

As shown in FIG. 1, a front panel 20 is provided on the front side of the driver's seat 5A of the control unit 5, and a side panel 30 is provided on the left side.

A monitor 21 for displaying the traveling speed of the traveling device 2 and the like is provided in the central portion of the front panel 20, and a turning lever 22 for performing a turning operation of the machine body and the like is provided on the right side of the monitor 21. Further, the swivel angle of the swivel lever 22 is measured by a swivel sensor 22A provided at the lower part of the swivel lever 22.

A main shift lever 31 for operating the HST provided between the engine E and the transmission to accelerate or decelerate the traveling speed of the traveling device 2 is provided on the front portion of the side panel 30, and is provided on the rear side of the main shifting lever 31. Is provided with an auxiliary speed change lever 32 that operates a transmission to accelerate or decelerate the traveling speed of the traveling device 2.

On the left side of the main speed change lever 31, a rescue switch 33 for raising the cutting device 3 from the soil surface to a predetermined height and moving it to a rescue posture, and an emergency stop switch 34 for stopping the drive of the engine E when an abnormality occurs are provided. ing. Further, when the rescue switch 33 is input, the hydraulic cylinder 33A that raises and lowers the cutting device 3 is driven.

On the left side of the auxiliary speed change lever 32, a start lever 35 for activating the control motor 42 built in the discharge switching device 40, which will be described later, for switching the drive of the straw discharge guide body 16 and the straw discharge cutter 18 is provided and started. On the left side of the lever 35, a switching lever 36 for switching the drive of the straw exhausting guide body 16 and the straw exhausting cutter 18 is provided.

As shown in FIG. 7, on the right wall of the threshing device 4, a straw culm transport guide body 16 for discharging a predetermined amount of straw culm to the rear of the machine body and a straw culm cutter 18 for shredding the straw culm are shredded. The discharge switching device 40 for switching the drive of the culm is provided.

As shown in FIG. 10 and the like, the discharge switching device 40 is fixed to the motor 42 provided on the right side of the inverted L-shaped fixing plate 41 and to the rotating shaft 42A of the motor 42 on the left side of the fixing plate 41. It is formed from a rotating plate 43 having a substantially two isosceles triangle shape. Further, the rotation angle of the rotation shaft 42A is measured by an angle sensor such as a potentiometer installed on the rotation shaft 42A.

A front portion of a substantially arcuate cutter link (“first link” in claim) 44 projecting downward is connected to one side of the bottom portion of the rotating plate 43, and is connected to the other side of the bottom portion of the rotating plate 43. Is connected to a guide link (“second link” in claim) 45 having a substantially arc shape protruding upward. Further, the rear portion of the threshing wire (“third wire” in claim) 47 arranged forward is connected to the top of the rotating plate 43, and the rear portion of the cutter link 44 is directed backward. The front part of the cutter wire (“first wire” in the claim) 48 to be arranged is connected, and the guide wire (in the claim) to be arranged rearward is connected to the rear part of the guide link 45. The front portion of the "second wire") 49 is connected.

The front portion of the threshing wire 47 is connected to a threshing clutch (not shown) that transmits the output rotation of the engine E to the handling cylinder 14 and the like. When the threshing wire 47 moves rearward, the threshing clutch is connected to drive the handling cylinder 14 and the like. On the other hand, when the threshing wire 47 moves forward, the threshing clutch is disengaged and the driving of the handling cylinder 14 and the like is stopped.

The rear portion of the cutter wire 48 is connected to a cutter clutch (not shown) that transmits the output rotation of the engine E to the straw cutter 18. When the cutter wire 48 moves forward, the cutter clutch is engaged and the straw cutter 18 is driven. On the other hand, when the cutter wire 48 moves rearward, the connection of the cutter clutch is released and the driving of the straw cutter 18 is stopped.

The rear portion of the guide wire 49 is connected to the straw transport guide body 16. When the guide wire 49 moves forward, the straw discharge transport guide body 16 rotates counterclockwise in FIG. 6 around a support shaft extending in the left-right direction of the lower end portion of the straw discharge transport guide body 16. However, below the straw-removing transport device 15, the longitudinal direction is moved to a guiding posture along the extension in the front-rear direction of the machine body. That is, in this guidance posture, the straw culm transported by the straw transport device 15 is guided backward as it is, and is discharged to the outside of the machine without passing through the straw cutter 18. On the other hand, when the guide wire 49 moves backward, the straw-removing guide body 16 rotates clockwise around the support axis at the lower end portion in FIG. 6 and moves to an upright evacuation posture. In this retracted posture, the straw-removing guide body 16 is in a state where the upper part of the straw-removing cutter 18 is opened, so that the straw-grained culm transported by the straw-removing transport device 15 falls to the straw-removing cutter 18. Shredded.

As a result, one motor 42 can operate the handling cylinder 14, the straw-removing guide body 16, and the straw-removing cutter 18 to drive and stop the drive, reducing the number of parts and reducing the maintenance work load. be able to.

As shown in FIG. 7, the longitudinal direction of the discharge switching device 40 is provided along the front-rear direction of the machine body. In the right side view, the discharge switching device 40 transfers the first threshing cylinder 50 that transfers the threshed and sorted grains to the grain tank 7, and the second fried grain that transfers the second product such as the stabbed grain to the threshing device 4 again. It is provided behind the grain tube (“threshing tube” in the claim) 51 and in front of the cutting processing chamber 17. As a result, the space formed behind the first fried grain cylinder 50 and the second fried grain cylinder 51 can be effectively utilized.

Further, the discharge switching device 40 includes a grain removal wire 47 arranged forward from the discharge switching device 40, and a cutter wire 48 and a guide wire 49 arranged rearward from the discharge switching device 40. The length is the same, that is, the shortest wire length of the degraining wire 47, the cutter wire 48, and the guide wire 49 is 90% or more of the longest wire length. It is preferable to provide the wire at the above position. As a result, the force for moving the threshing wire 47 backward and the force for moving the cutter wire 48 and the guide wire 49 forward can be made substantially the same, so that a small motor 42 can be used. The discharge switching device 40 can be formed more compactly.

As shown in FIGS. 8 and 9, the threshing wire 47 extends forward through between the right wall of the threshing device 4 and the second freshing cylinder 51 and extends forward to the threshing arm of the threshing clutch ("in claim". It is connected to the "third arm") 55. The cutter wire 48 extends rearward through below the rear wall of the threshing device 4 and is provided on the left wall of the cutting processing chamber 17 as a cutter arm (“first arm” in the claim). It is connected to 56. The guide wire 49 extends to the rear through an opening formed in the rear wall of the threshing device 4 and is connected to the lower part of the support shaft to the guide arm (“second arm” in the claim) 57. It is linked.

When the start lever 35 of the side panel 30 is moved from the rear side to the front side, the start of the motor 42 of the discharge switching device 40 is started.

When the switching lever 36 of the side panel 30 is moved from the rear side to the front side, that is, when the switching lever 36 is moved from the straw transfer guide body side to the cutting cutter side, the rotating shaft 42A rotates clockwise as shown in FIG. Then, the threshing wire 47 moves rearward from the neutral position via the rotating plate 43, the cutter wire 48 moves forward from the neutral position via the rotating plate 43 and the cutter link 44, and the guide wire 49 Moves rearward from the neutral position via the rotating plate 43 and the guide link 45.

As a result, the threshing clutch is connected to drive the handling cylinder 14, and the cutter clutch is connected to drive the straw cutter 18. On the other hand, the support shaft does not rotate, and the straw-removing guide body 16 maintains a shunting posture. In this specification, this state is referred to as a handling cylinder / straw cutter operating state.

In this state, when the switching lever 36 of the side panel 30 is moved from the front side to the rear side, that is, the switching lever 36 is moved from the cutting cutter side to the straw transfer guide body side, first, as shown in FIG. 11, the rotating shaft The 42A rotates counterclockwise, the threshing wire 47 moves to the front neutral position via the rotating plate 43, and the cutter wire 48 moves to the rear neutral position via the rotating plate 43 and the cutter link 44. It moves and the guide wire 49 moves to the front neutral position via the rotating plate 43 and the guide link 45.

As a result, the threshing clutch is disconnected and the handling cylinder 14 is stopped, the cutter clutch is disconnected and the straw cutter 18 is stopped, the support shaft does not rotate, and the straw transport guide body 16 is in a retracting posture. maintain. In addition, in this specification, this state is referred to as a handling cylinder, a straw excretion cutter, and a straw excretion transport guide body stop state.

Next, when a predetermined time elapses, as shown in FIG. 13, the rotation shaft 42A further rotates clockwise, and the grain removal wire 47 moves rearward from the neutral position via the rotation plate 43 for the cutter. The wire 48 moves rearward from the neutral position via the rotating plate 43 and the cutter link 44, and the guide wire 49 moves forward via the rotating plate 43 and the guide link 45.

As a result, the threshing clutch is connected to drive the handling cylinder 14, the support shaft rotates counterclockwise, and the straw-removing guide body 16 moves to the guide posture. On the other hand, the disconnection of the cutter clutch is maintained and the drive stop of the straw cutter 18 is maintained. In this specification, this state is referred to as a handling cylinder / straw transport guide body operating state.

In the description of the drive of the discharge switching device 40 described above, the case where the switching lever 36 is moved from the front side to the rear side has been described, but the switching lever 36 is moved from the rear side to the front side, that is, the straw is discharged from the straw transport guide body side. When moving to the cutter side, the handling cylinder / straw transport guide body operating state shown in FIG. 13, the handling cylinder / straw cutter / straw discharge guide body stopped state shown in FIG. 12, and the handling cylinder / body shown in FIG. The state switches in order to the straw cutter operating state.

As shown in FIG. 14, the controller 25 has a built-in timer 25A. Thereby, for example, the time between the switching of the switching lever 36 and the switching of the rotation direction of the motor 42 can be measured.

On the input side of the controller 25, a swivel sensor 22A for measuring the swivel angle of the swivel lever 22, a retreat switch 33 for moving the cutting device 3 to the retreat posture, and an emergency stop switch 34 for stopping the drive of the engine E when an abnormality occurs. A start lever 35 for activating the motor 42 of the discharge switching device 40, and a switching lever 36 for switching the drive of the straw discharge guide body 16 and the discharge straw cutter 18 are connected via a predetermined input interface circuit.

On the output side of the controller 25, a monitor 21 for displaying the combine state, a hydraulic cylinder 33A for raising and lowering the cutting device 3, and a motor 42 for the discharge switching device 40 are connected via a predetermined output interface circuit.

<Driving method of discharge switching device>
As shown in FIG. 15, in step S1, the controller 25 determines whether or not the start lever 35 has moved from the rear side to the front side, and if it determines that the start lever 35 is located on the front side, The process proceeds to step S2, and if it is determined that the start lever 35 is located on the rear side, the process proceeds to step S3. Further, the position of the start lever 35 is measured by a sensor such as a potentiometer provided at the lower part of the start lever 35.

In step S2, the controller 25 activates the motor 42 and proceeds to step S4.

In step S3, the controller 25 stops the motor 42 and returns to step S1.

In step S4, the controller 25 determines whether or not the emergency stop switch 34 is input, and if it determines that the emergency stop switch 34 is input, returns to step S3 and the emergency stop switch 34 is input. If it is determined that there is no such procedure, the process proceeds to step S5. As a result, when the emergency stop switch 34 is input, the motor 42 is stopped, the handling cylinder 14 and the like are stopped, and the safety of the working environment can be enhanced.

In step S5, the controller 25 determines whether or not the save switch 33 for moving the cutting device 3 to the save posture is input, and if it is determined that the save switch 33 is not input, returns to step S3 and saves. If it is determined that the switch 33 is input, the process proceeds to step S6. Further, the input of the rescue switch 33 is restricted to be released when the motor 42 is being driven. When the traveling device 2 is traveling, the motor 42 can be stopped.

In step S6, when the controller 25 determines whether the switching lever 36 is on the front cutting cutter side or the rear straw discharging guide body side, and determines that the switching lever 36 is located on the cutting cutter side. Proceeds to step S7, and if it is determined that the switching lever 36 is located on the straw transport guide body side, the process proceeds to step S12. Further, the position of the switching lever 36 is measured by a sensor such as a potentiometer provided at the lower part of the switching lever 36.

In step S7, as shown in FIG. 12, the controller 25 rotates the rotating shaft 42A of the motor 42 clockwise to move the grain removal wire 47 backward from the neutral position, and moves the cutter wire 48 forward from the neutral position. The guide wire 49 is moved rearward from the neutral position to proceed to step S8. As a result, the threshing clutch is connected to drive the feed chain 12, the handling cylinder 14, and the straw-removing transport device 15 of the threshing device 4, and the cutter clutch is connected to drive the straw-discharging cutter 18. On the other hand, the support shaft does not rotate, the straw-removing guide body 16 maintains a retreat posture, and the straw-removing guide body 16 stops.

In step S8, the controller 25 determines whether the switching lever 36 is on the cutting cutter side on the front side or the straw discharge transport guide body side on the rear side, and determines that the switching lever 36 is located on the cutting cutter side. Return to step S7, and if it is determined that the switching lever 36 is located on the straw transport guide body side, the process proceeds to step S9.

In step S9, as shown in FIG. 11, the controller 25 rotates the rotating shaft 42A of the motor 42 in the counterclockwise direction to move the grain removal wire 47 from the rear to the neutral position, and the cutter wire 48 from the front to the neutral position. It is moved to the position, the guide wire 49 is moved from the rear to the neutral position, and the process proceeds to step S10. As a result, the connection of the threshing clutch is disengaged, the feed chain 12, the handling cylinder 14, and the straw discharging device 15 of the threshing device 4 are stopped, the connection of the cutter clutch is disengaged, the straw excretion cutter 18 is stopped, and the support shaft. Since the straw-removing guide body 16 maintains a shunting posture and the straw-removing guide body 16 stops without rotating, the straw-removing means is being switched from the straw-discharging cutter 18 to the straw-removing transport guide body 16. It is possible to prevent the straw grain slag from being clogged in the rear part of the straw transport device 15.

In step S10, the controller 25 determines whether or not the threshing clutch is disconnected and a predetermined time has elapsed, and if it is determined that the predetermined time has not elapsed, the controller 25 repeats step S10 and the predetermined time has elapsed. If it is determined, the process proceeds to step S11. Further, the predetermined time can be set on the monitor 21 at an arbitrary time, and while the predetermined time has not elapsed, the monitor 21 displays the switching state and the like. As a result, the safety of the working environment can be enhanced.

In step S11, as shown in FIG. 13, the controller 25 further rotates the rotation shaft 42A of the motor 42 in the counterclockwise direction to move the grain removal wire 47 from the neutral position to the rear, and moves the cutter wire 48 to the neutral position. The guide wire 49 is moved forward from the neutral position to return to step S1. As a result, the threshing clutch is connected, the feed chain 12, the handling cylinder 14, and the straw-removing transport device 15 of the threshing device 4 are driven, the support shaft rotates counterclockwise, and the straw-removing transport guide body 16 is in the guide posture. Move and drive. On the other hand, the disconnection of the cutter clutch is maintained and the straw cutter 18 is subsequently stopped.

In step S12, the controller 25 determines whether or not the turning lever 22 is operated to turn the aircraft, and if it determines that the aircraft is turning, the controller 25 proceeds to step S7 and the aircraft is not turning. If it is determined that the vehicle is going straight, the process proceeds to step S13. As a result, it is possible to prevent the discharged straw from being discharged from the straw discharging guide body 16 and prevent the discharged straw from being entangled with the traveling device 2. Further, whether or not the machine is turning is measured by a turning sensor 22A such as a potentiometer provided at the lower part of the turning lever 22 for the turning angle of the turning lever 22 for turning the machine. It should be noted that whether or not the aircraft is turning can be measured by a camera image mounted on the aircraft, GPS, or the like instead of the turning sensor 22A.

In step S13, as shown in FIG. 13, the controller 25 rotates the rotation shaft 42A of the motor 42 in the counterclockwise direction to move the grain removal wire 47 from the neutral position to the rear, and moves the cutter wire 48 from the neutral position. It is moved backward, and the guide wire 49 is moved forward from the neutral position to proceed to step S14. As a result, the threshing clutch is connected to drive the feed chain 12, the handling cylinder 14, and the straw-removing transport device 15 of the threshing device 4, the support shaft rotates, and the straw-removing guide body 16 moves to the guide posture and is driven. do. Further, the connection of the cutter clutch is released and the straw cutter 18 is stopped.

In step S14, the controller 25 determines whether the switching lever 36 is on the cutting cutter side on the front side or on the straw transport guide body side on the rear side, and determines that the switching lever 36 is located on the straw transport guide body side on the rear side. In that case, the process returns to step S12, and if it is determined that the switching lever 36 is located on the cutting cutter side, the process proceeds to step S15.

In step S15, as shown in FIG. 11, the controller 25 rotates the rotating shaft 42A of the motor 42 clockwise to move the threshing wire 47 from the rear to the neutral position, and the cutter wire 48 from the rear to the neutral position. , The guide wire 49 is moved from the front to the neutral position, and the process proceeds to step S16. As a result, the connection of the threshing clutch is disengaged, the feed chain 12, the handling cylinder 14, and the straw discharging device 15 of the threshing device 4 are stopped, the support shaft rotates clockwise, and the straw discharging guide body 16 is in the shunting posture. Since the cutter clutch is subsequently disconnected and the straw excretion cutter 18 is stopped, the straw culm is particularly affected during the switching of the ejection means from the straw excretion transport guide body 16 to the straw excretion cutter 18. It is possible to prevent the rear part of the straw-removing transport device 15 from being clogged.

In step S16, the controller 25 determines whether or not the threshing clutch is disconnected and a predetermined time has elapsed, and if it is determined that the predetermined time has not elapsed, the controller 25 repeats step S16 and the predetermined time has elapsed. If it is determined, the process proceeds to step S17. Further, the predetermined time can be set on the monitor 21 at an arbitrary time, and while the predetermined time has not elapsed, the monitor 21 displays the switching state and the like. As a result, the safety of the working environment can be enhanced.

In step S17, as shown in FIG. 12, the controller 25 further rotates the rotation shaft 42A of the motor 42 clockwise to move the threshing wire 47 from the neutral position to the rear, and moves the cutter wire 48 from the neutral position. The guide wire 49 is moved forward and the guide wire 49 is moved backward from the neutral position to return to step S1. As a result, the threshing clutch is connected to drive the feed chain 12, the handling cylinder 14, and the straw-removing transport device 15 of the threshing device 4, and the cutter clutch is connected to drive the straw-discharging cutter 18. On the other hand, the support shaft does not rotate, the straw-removing guide body 16 maintains a retreat posture, and the straw-removing guide body 16 stops.

INDUSTRIAL APPLICABILITY The present invention can be applied to an agricultural work vehicle provided with a cutting processing chamber equipped with a straw-removing guide body and a straw-removing cutter behind the threshing device.

1 Aircraft frame 2 Traveling device 3 Cutting device 4 Threshing device 5 Control unit 7 Glen tank 15 Straw discharge transport device 16 Straw transport guide body 17 Cutting processing chamber 18 Straw cutter 40 Discharge switching device
41 Fixed plate 42 Motor 42A Rotating shaft 43 Rotating plate 44 Cutter link (first link)
45 Guide link (second link)
47 Threshing wire (3rd wire)
48 Cutter wire (1st wire)
49 Guide wire (second wire)
51 2nd Winnowing (Winnowing)
55 Threshing arm (3rd arm)
56 Cutter arm (1st arm)
57 Guide arm (second arm)
E engine

Claims (7)

A traveling device (2) is provided on the lower side of the machine frame (1) on which the engine (E) is mounted, a cutting device (3) is provided on the front side of the machine frame (1), and the rear left side of the cutting device (3). In a combine harvester provided with a threshing device (4), a control unit (5) on the rear right side of the cutting device (3), and a grain tank (7) on the rear side of the control unit (5).
On the rear side of the threshing device (4), a straw transport guide body (16) for discharging the straw culms transported by the straw transport device (15) of the threshing device (4) to the outside, and the straw transport guide body (16). A straw cutter (18) is provided under the straw transport guide body (16) to shred the straw culm and carry it out.
On the right wall of the threshing device (4), a discharge switching device (40) for switching the operating state of the straw discharge guide body (16) and the straw discharge cutter (18) is provided.
In the right side view, the combine is characterized in that the discharge switching device (40) is provided on the front side of the cutting processing chamber (17) in which the straw cutter (18) is installed. The combine according to claim 1, wherein the discharge switching device (40) is provided on the rear side of a frying cylinder (51) for freshing the second product of the threshing device (4) in a right side view. The combine according to claim 1 or 2, wherein the discharge switching device (40) is provided with the longitudinal direction along the front-rear direction. The discharge switching device (40) connects and disconnects the clutch that transmits the output rotation of the engine (E) to the straw cutter (18) via the first wire (48) to the first arm (56). The first link (44) connected to the first link (44) and the second arm (57) for rotating the straw-removing guide body (16) into the shunting posture and the guiding posture are connected via the second wire (49). The two links (45), the rotating plate (43) to which the front portions of the first link (44) and the second link (45) are rotatably fixed, and the motor (42) for rotating the rotating plate (43). )
The combine according to any one of claims 1 to 3, wherein the lengths of the first wire (48) and the second wire (49) are formed to have substantially the same length. In the axial view of the rotating shaft (42A) of the motor (42), the front portion of the first wire (48) and the second wire (4) are on the same radius from the rotating shaft (42A) of the rotating plate (43). 49) The combine according to claim 4, wherein the front portion is rotatably fixed. A third wire (47) connected to a third arm (55) for connecting and disconnecting a clutch for transmitting the output rotation of the engine (E) to the threshing device (4) is attached to the rotating plate (43). Fixed rotatably,
The combine according to claim 4 or 5, wherein the length of the third wire (47) is substantially the same as the length of the first wire (48) and the second wire (49). In the axial view of the rotating shaft (42A) of the motor (42), the front portion of the first wire (48) and the second wire are on the same radius from the rotating shaft (42A) of the rotating plate (43). The combine according to claim 6, wherein the front portion of (49) and the rear portion of the third wire (47) are rotatably fixed.

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