JP2019110856A - Crop harvester - Google Patents

Abstract

To suppress properly inclination in a cross direction of a machine body following work, in a crop harvester including a storage part for storing harvested crops, on the rear of the machine body.SOLUTION: A crop harvester includes a harvesting part 11 for harvesting crops A in a field, and a storage part 8 provided on the rear of a machine body 1, for storing harvested crops A; further includes a balance weight 35 provided on the front of the machine body 1, and an inclination sensor for detecting an inclination angle in a cross section of the machine body 1; and furthermore includes a weight position change part 40 for changing, to the cross section, the position of the balance weight 35 to the machine body 1 so that the machine body 1 is maintained horizontally in the cross section, based on a detection value from the inclination sensor.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a crop harvester that harvests crops in a field and stores them in an airframe.

  An example of a crop harvester as described above is disclosed in US Pat. In Patent Document 1, a reservoir is provided at the rear of the airframe, and crops are put into the reservoir as the field crops are harvested. When the reservoir is full, the work is paused to transfer the crops of the reservoir to another vehicle or the like, after which the work is resumed.

JP 2007-202405 A

  In patent document 1, the storage part is equipped in the rear part of the fuselage from the relation of arrangement of a conveyance device of crops, a work deck for workers, etc. As a result, the storage section (work) starts to work from an empty state, and as the crop is stored in the storage section, the weight of the storage section (crop) increases. May be

As described above, when the airframe falls down, the front of the airframe moves upward from the field, which may hinder the harvest of crops in the field.
An object of the present invention is to provide a crop harvester provided with a storage unit for storing harvested crops at the rear of an airframe, so as to be able to appropriately suppress the longitudinal inclination of the airframe accompanying the operation.

The crop harvester of the present invention is
The harvesting department, which harvests crops in the field,
A reservoir provided at the rear of the airframe for storing the crop harvested by the harvester;
It is equipped with a balance weight provided at the front of the fuselage, and a tilt sensor that detects the tilt angle of the fuselage in the longitudinal direction.
A weight position changing unit is provided to change the position of the balance weight relative to the airframe in the front-rear direction so that the airframe is maintained horizontally in the front-rear direction based on the detection value of the tilt sensor.

According to the present invention, even if the weight of the rear storage section of the airframe becomes heavy as the crops are stored, it is possible to suppress the downswing of the airframe by the balance weight at the front of the airframe.
As described above, when the balance weight is provided at the front of the vehicle, according to the present invention, the tilt sensor for detecting the tilt angle in the front-rear direction of the vehicle and the weight position change unit for changing the position of the balance weight in the front-rear direction are provided. It is done.

  As a result, when the weight of the storage section becomes heavier as the crops are stored in the storage section, the position of the balance weight with respect to the airframe is located on the front side (from the airframe to the front) based on the detection value of the inclination sensor. (The side away from the rear side), the rear down state of the airframe is suppressed as the airframe is kept horizontal in the front-rear direction.

  When the weight of the storage unit is reduced by transferring the crops of the storage unit to another transport vehicle etc., the position of the balance weight with respect to the aircraft is changed to the rear side (the side approaching the aircraft) based on the detection value of the inclination sensor. As a result, it is possible to suppress the forward lowering of the airframe as the airframe is maintained horizontally in the front-rear direction.

  As described above, according to the present invention, the position of the balance weight at the front of the airframe is automatically changed in the front-rear direction based on the detection value of the inclination sensor. Regardless of the change, the airframe can be maintained horizontally in the front-rear direction, and the harvest performance of the crop harvester can be improved.

In the present invention,
The harvest section
It is preferable that the right and left carriers be rotationally driven so as to hold the crop on the field from the right and left at the front of the machine body and lift it from the field and convey the crop to the rear side of the machine body.

  For example, in some harvesting machines such as radish, carrot, cabbage and turnip, the right and left carriers pinch and lift the crop on the field from the right and left sides and transport them to the rear of the machine. In such a crop harvester, since the crop on the field is held at the front of the carrier, the height from the field to the front of the carrier is maintained at a certain height suitable for clamping the crop. There is a need.

  According to the present invention, in the crop harvester provided with the transport body as described above, the body is maintained horizontally in the front-rear direction regardless of the change in weight of the storage section at the rear of the body, from the field to the front of the transport body Height will be maintained at a constant height. This makes the invention suitable for a crop harvester equipped with a carrier as described above.

In the present invention,
The weight position change unit
A support unit to which the plurality of balance weights are attached, and an actuator for changing the position of the support unit relative to the airframe in the front-rear direction;
It is preferable that the number of balance weights attached to the support can be changed.

  According to the present invention, for example, when the storage unit is changed to a storage unit having a different capacity, the number of balance weights attached to the support unit is changed according to the condition of the field, the growth condition of the crop, etc. The balance weight can be attached to the support.

It is a side view of a radish harvester. It is a top view of a radish harvester. It is sectional drawing which shows the support structure of a conveying apparatus. It is a top view of the vicinity of a weight position change part. It is a figure which shows the connection state of a control apparatus and each part.

  The radish harvester which is an example of a crop harvester is shown by FIGS. 1-5. F indicates “forward”, B indicates “rearward”, U indicates “upward”, and D indicates “downward”. R indicates "rightward" and L indicates "leftward".

(Whole structure of radish harvester)
As shown in FIG. 1 and FIG. 2, the airframe 1 is supported by the right and left crawler type traveling devices 2, the driving unit 3 is supported on the right front of the airframe 1, and the balance is held on the left front of the airframe 1. The weight 35 is supported. The transport device 4 is supported along the front-rear direction on the left side of the fuselage 1, the separating device 5 is supported on the front of the transport device 4, and the auxiliary wheel 6 and the subsoiler 17 are supported on the front of the fuselage 1. ing.

The conveyer 7 is supported along the left-right direction at a lower position at the rear of the conveyer 4, and the reservoir 8 is supported at the rear of the machine body 1, and between the conveyer 7 and the reservoir 8, A working deck 9 for auxiliary workers is provided.
A roof 10 is supported on the upper portion of the airframe 1, and the roof 10 extends from the operation unit 3 to the storage unit 8 in the front-rear direction and extends from the operation unit 3 to the transport device 4 in the left-right direction.

(Configuration of transport device)
As shown in FIGS. 1, 2 and 3, the transport device 4 is generally in a back-to-back configuration (the front is at a low position near the field and the rear is at a high position above the transport conveyor 7). Down).

  Right and left support frames 13, right and left first conveyor belts 11 (corresponding to harvesters) (corresponding to conveyors), right and left second conveyor belts 12 (corresponding to harvesters) The cutter 14 and the like are provided.

  An arched support frame 16 is connected across the front of the right and left support frames 13. The right and left rotating bodies 15 are supported at the front end portion and the rear end portion of the support frame 13, and the first conveying belt 11 is attached across the front and rear rotating bodies 15 so that the entire first conveying belt 11 is Is supported in the form of upside down.

  The second conveyor belt 12 is supported from the lower side of the middle portion in the front-rear direction of the first conveyor belt 11 along the first conveyor belt 11 in a backward upward (downward) manner. A cutter 14 is supported between the first conveyor belt 11 and the second conveyor belt 12 at the rear of the second conveyor belt 12.

(Configuration of separation device)
As shown in FIGS. 1, 2 and 4, the separation device 5 includes four sets of separation belts 18 and 19 integrally formed such that a large number of arm portions 18a and 19a are spaced apart, in the vertical direction. The support frame 20 is supported at the front of the support frame 13.

  The two sets of separation belts 19 are rotatably supported by the support frame 20 at intervals in the left-right direction such that the arm portions 19a of the separation belt 19 are directed in the left-right direction. At the front of the front portion 11, the arm portions 19a of the right and left separation belts 19 face each other.

  At the front of the separation belt 19, right and left separation belts 18 are rotatably supported by the support frame 20 at intervals in the left-right direction, and an arm 18a of the separation belt 18 faces the front.

(Supporting structure of transport device)
As shown in FIGS. 1, 2, 3 and 4, the upper link 22 and the lower link 23 are vertically swingably supported at the left front of the airframe 1, and the longitudinal link is provided at the front of the upper link 22 and the lower link 23. 24 are connected to form a quadruple link.

  An auxiliary wheel 6 and a subsoiler 17 are supported at the front of the upper link 22 and the lower link 23, and a hydraulic cylinder 25 for raising and lowering the upper link 22 and the lower link 23 is provided.

  The support link 26 is swingably supported around the lateral center axis P1 of the front portion of the lower link 23, and the support link 27 is swingable around the lateral center axis P2 of the upper portion of the support link 26. It is supported. A hydraulic cylinder 28 is connected across the support links 26 and 27, and an upper portion of the support link 27 is swingably connected to an upper portion of the support frame 16.

  A guide frame 29 is connected upward and downward to the left rear of the machine body 1, a support frame 30 is supported slidably in the vertical direction along the guide frame 29, and a hydraulic cylinder 31 for slidingly driving the support frame 30 up and down is provided. It is equipped. The rear portion of the support frame 13 is swingably connected to the upper end portion of the support frame 30.

  With the above structure, by sliding the support frame 30 up and down by the hydraulic cylinder 31, the height of the rear portion of the support frame 13 (second transport belt 12) can be changed. In this case, the displacement of the support frame 13 in the front-rear direction due to the vertical slide is absorbed by the support links 26, 27 swinging back and forth around the axis P1.

  As described in (Flow of harvesting of radish by transport device and separation device), in harvesting of radish A (corresponding to crop), for example, when radish A is long, the support frame 13 (second transport belt 12) You just have to raise the height of the back a little. When the radish A is short, the height of the rear portion of the support frame 13 (second conveying belt 12) may be slightly lowered. Thus, the vertical distance between the rear end portion of the second conveyor belt 12 and the conveyor 7 can be matched to the length of the radish A.

  The hydraulic cylinder 28 is extended and contracted, and the support links 26 and 27 are flexed to change the position of the upper portion of the support link 27 up and down, so that the front portion of the first conveyor belt 11 (support frame 13) You can change the height from the field.

(Swinging up the left rear of the roof)
As shown in FIGS. 1 and 3, in the roof 10, the left rear portion 10 a of the roof 10 located on the upper side of the rear portion of the transport device 4 is separated from the main body portion of the roof 10.

  The left rear portion 10a of the roof 10 is supported so as to swing up and down around the axial center P4 in the front-rear direction of the roof 10, and provided with a hydraulic cylinder 47 for driving the left rear portion 10a of the roof 10 to swing up and down There is.

  As described in the above (support structure of the transfer device), when the rear portion of the support frame 13 (second transfer belt 12) is moved up and down by the hydraulic cylinder 31, the support frame 30 is the middle portion and middle portion of the upper and lower slide range. When positioned from the lower side, the left rear portion 10 a of the roof 10 is in a posture parallel to the body portion of the roof 10.

  When the support frame 30 moves upward from the middle part of the upper and lower slide range, the left rear portion 10 a of the roof 10 is automatically operated upward by the hydraulic cylinder 47, and the rear portion of the transport device 4 and the left rear portion of the roof 10 Contact with 10a is avoided.

(Support structure of separation device)
As shown in FIGS. 1, 2 and 4, the support link 32 is vertically swingably supported at the front of the support frame 13, and the front of the support link 32 swings to the lower part of the support frame 20. It is connected freely.

The operation arm 33 is supported so as to be pivotable up and down around the left-right axial center P3 of the left front of the vehicle body 1, and the front portion of the operation arm 33 is pivotally connected to the upper portion of the support frame 20 ing. A hydraulic cylinder 34 is connected across the lower link 23 and the operation arm 33.
According to the above-described structure, the height of the separating device 5 from the field can be changed by driving the operating arm 33 up and down by the hydraulic cylinder 34.

  The support links 26 and 27 and the hydraulic cylinder 34 are supported by the lower link 23. When the upper link 22 and the lower link 23 (the auxiliary wheel 6 and the subsoiler 17) are moved up and down by the hydraulic cylinder 25 at the time of turning or the like of the vehicle body 1, the front part of the transfer device 4 and the separating device 5 move up and down together.

  The support frame 13 and the support frame 20 are connected via the support link 32. Even if the height from the field of the front portion of the first conveyor belt 11 (support frame 13) is changed by the hydraulic cylinder 28, this action is absorbed by the support link 32, and the height of the separation device 5 does not change. .

  Similarly, even if the height from the field of the separation device 5 is changed by the hydraulic cylinder 34, this action is absorbed by the support link 32, and the height of the front portion of the first conveyor belt 11 (support frame 13) is There is no change.

(Flow of harvesting of radish by conveying device and separating device)
As shown in FIGS. 1, 2 and 4, as the airframe 1 advances, the radish A of the row to be harvested enters between the right and left separation belts 18.

  Separation belts 18 so that arm portions 18a facing forward in the right and left separation belts 18 move upward between the leaves A1 of the radish A of the row to be harvested and the leaves A1 of the radish A of the adjacent row. Are rotationally driven to separate adjacent leaves A1 of the radish A from each other.

  Next, the separation belt 19 rotates so that the radish A of the row to be harvested enters between the right and left separation belts 19 and the opposing arm portions 19a of the right and left separation belts 19 move upward. Driven, leaves A1 of adjacent radish A are separated from each other in radish A of the row to be harvested.

  The first transport belt 11 is rotationally driven such that opposing portions of the right and left first transport belts 11 move rearward. Similarly, the right and left second conveyor belts 12 are also rotationally driven such that the opposing portions move rearward.

Leaves A1 of radish A in a row to be harvested enter between the right and left first conveyor belts 11 from the front of the right and left first conveyor belts 11, and are held by the right and left first conveyor belts 11 While being done, the radish A is lifted (extracted) from the field and transported to the rear side.
In this case, since the soil of the field is crushed by the subsoiler 17, the radish A is lifted (extracted) from the field without difficulty.

  The radish A is transported rearward by the first transport belt 11, and the lower portion of the first transport belt 11 in the leaf A1 of the radish A is pinched and transported by the right and left second transport belts 12, The upper portion of the second conveyance belt 12 in the leaf A1 is cut by the cutter 14.

  At the rear end of the second conveyor belt 12, the radish A falls from the second conveyor belt 12 onto the conveyor 7 and is conveyed to the right by the conveyor 7. The operator of the work deck 9 takes out the good radish A from the radish A conveyed by the conveyer 7 and arranges the radish A in the storage unit 8 in an aligned state, and the defective radish A is conveyed by the conveyer 7 It is discharged from the right end of the conveyer 7 to the field.

  In this case, the height of the rear portion of the support frame 13 (the second conveyance belt 12) is changed as described in the above (support structure of the conveyance device), and the rear end portion of the second conveyance belt 12 and the conveyance conveyor By adjusting the vertical interval of 7 to the length of the radish A, the radish A falls from the second conveyance belt 12 to the conveyance conveyor 7 without spilling at the rear end of the second conveyance belt 12 be able to.

The leaves A1 of the radish A are transported to the rear side by the first transport belt 11, and are discharged from the rear end of the first transport belt 11 to the field.
In this case, a guide plate 21 for guiding the leaves A1 of the radish A is provided so that the leaves A1 of the radish A fall substantially right below the rear end portion of the first conveyance belt 11.

(Structure of weight support for supporting balance weight)
As shown in FIGS. 2 and 4, a weight position changer 40 is provided at the left front of the vehicle 1.

  At the left front of the fuselage 1, rectangular pipe-shaped right and left guide portions 36 are connected to the center side (right side) of the upper link 22 and the lower link 23 in plan view along the longitudinal direction. Square pipe-shaped right and left slide portions 37 are inserted into the guide portions 36 and slidably supported in the front-rear direction along the guide portions 36.

  A support 38 is connected to the front of the right and left slides 37, and a balance weight 35 is attached to the support 38. A return type hydraulic cylinder 39 (corresponding to an actuator) is connected across the machine body 1 and the support 38.

  By expanding and contracting the hydraulic cylinder 39, the support portion 38 and the slide portion 37 can be integrally moved in the front-rear direction (the position of the balance weight 35 can be changed in the front-rear direction).

  In this case, the support portion 38 and the balance weight 35 move in the front-rear direction across the rear limit position B1 and the front limit position B2 along the center side (right side) of the upper link 22 and the lower link 23 in plan view. Do. The front limit position B2 is a position on the rear side with respect to the auxiliary wheel 6, and the support portion 38 and the balance weight 35 do not contact the auxiliary wheel 6 even if the front limit position B2 is reached.

  As described above, the weight position changing unit 40 includes the guide portion 36, the slide portion 37, the support portion 38, the hydraulic cylinder 39, and the like. The plurality of balance weights 35 are arranged in the lateral direction on the support portion 38 and can be attached and removed, and the number of balance weights 35 attached to the support portion 38 can be arbitrarily set (changed).

  The left and right center position C2 of the reservoir 8 is biased to the right with respect to the left and right center position C1 of the right and left traveling devices 2 in plan view. The left and right center position C3 of the weight position changing portion 40 (supporting portion 38) is biased to the left (the opposite side to the left and right center position C2 of the storage portion 8).

(Configuration of control system of weight position change unit)
As shown in FIG. 5, a control valve 42 is provided which operates to supply and discharge hydraulic oil to the hydraulic cylinder 39 to extend and contract the hydraulic cylinder 39, and the control valve 41 is operated by the control device 41.

  A mode setting unit 43 for setting an automatic mode and a manual mode, and a manual operation unit 44 are provided in the operation unit 3, and operation signals of the mode setting unit 43 and the manual operation unit 44 are input to the control device 41 . The mode setting unit 43 and the manual operation unit 44 can be manually operated by the operator of the operation unit 3.

  A tilt sensor 45 is provided on the fuselage 1 to detect the tilt angle of the fuselage 1 in the front-rear direction, and a position sensor 46 is provided to sense that the support portion 38 is positioned at the rear limit position B1 and the front limit position B2, Detection values of the inclination sensor 45 and the position sensor 46 are input to the control device 41.

(Actuation of weight position change unit in automatic mode)
In the weight position changing unit 40, when the balance weight 35 is not attached to the support portion 38 and the storage portion 8 is empty, the entire center of gravity of the fuselage 1 etc. is the center of the traveling device 2 in the front-rear direction. It is set to a position (or a position slightly on the front side from the center position in the front-rear direction of the traveling device 2).

  When the operation is started in the above-described state, the support 38 is positioned at the rear limit position B1 and the balance weight 35 is attached to the support 38. As a result, the entire center of gravity moves slightly to the front, and in this state, the mode setting unit 43 automatically sets the mode and starts work.

  In the automatic mode, the control valve 42 is automatically operated by the control device 41 based on the detection of the inclination sensor 45 and the position sensor 46 as described below, and the hydraulic cylinder 39 is extended and contracted to support the support 38 and The position of the balance weight 35 is automatically changed.

  As the radish A is stored in the storage section 8 as the work progresses, the entire center of gravity gradually moves to the rear side. In this case, when the tilt sensor 45 detects that the airframe 1 is in the forward lowered state or in the horizontal state, the support 38 and the balance weight 35 do not move from the rear limit position B1.

  When the center of gravity of the whole moves backward with progress of the work and storage of the radish A in the storage part 8 and the downturn state of the airframe 1 is detected by the inclination sensor 45, the support part 38 and the balance weight As 35 automatically moves to the front side, the entire center of gravity is returned to the front side so that the airframe 1 returns to the horizontal state. When the machine 1 returns to the horizontal state, the support 38 and the balance weight 35 automatically stop.

  As described above, as many radishes A are stored in the storage portion 8 as the work progresses, the support portion 38 and the balance weight 35 automatically move to the front side, and the airframe 1 is horizontal. It is maintained in the state.

  The position sensor 46 detects that the support portion 38 and the balance weight 35 are positioned at the front limit position B2, but when the tilt sensor 45 detects the rearward lowering state of the machine 1, the machine 1 becomes horizontal. It is determined that it is difficult to return, and an alarm is activated.

  As a result, the worker temporarily suspends the work and increases the number of balance weights 35 to be attached in the support portion 38 or performs work such as replacing with a heavy weight. The radish A is taken out from the storage section 8 and transferred to another transport vehicle (not shown), or the storage section 8 is removed from the airframe 1, and another empty storage area 8 is attached to the airframe 1, etc.

  When the worker carries out the work as described above and the inclination sensor 45 detects that the machine body 1 has returned to the horizontal state, the support portion 38 and the balance weight 35 automatically move from the front limit position B2 to the rear side. Moving.

Next, based on the detection of the inclination sensor 45, the support portion 38 and the balance weight 35 automatically stop at the boundary position where the machine body 1 falls from the horizontal state to the backward state. Even if the support 38 and the balance weight 35 move to the rear limit position B1, the support 38 and the balance weight 35 automatically stop at the rear limit position B1 as long as the machine body 1 is maintained in the horizontal state.
Thus, the worker may resume work.

(Actuation of the weight position change unit in manual mode)
When the manual mode is set by the mode setting unit 43, the automatic change of the positions of the support portion 38 and the balance weight 35 as described above (the operation of the weight position changing unit in the automatic mode) is not performed.

  In the manual mode, when the operator operates the manual operation unit 44, the control valve 42 is operated by the control device 41 based on this operation, the hydraulic cylinder 39 is extended and contracted, and the support portion 38 and the balance weight 35 are on the front side. And move to the back side. Thus, the support 38 and the balance weight 35 can be positioned at desired positions between the rear limit position B1 and the front limit position B2.

If the tilt sensor 45 detects the rearward lowering state of the vehicle 1, an alarm is activated, and the operator may operate the manual operation unit 44 based on the alarm.
The position sensor 46 detects that the support portion 38 and the balance weight 35 are positioned at the front limit position B2, but when the tilt sensor 45 detects the rearward lowering state of the machine 1, the machine 1 becomes horizontal. It is determined that it is difficult to return, and an alarm different from the above-mentioned alarm is activated.

  As a result, the worker temporarily suspends the work and increases the number of balance weights 35 to be attached in the support 38, as described above (the operation of the weight position changing unit in the automatic mode). Work is carried out such as replacing with a heavy balance weight 35. The radish A is taken out from the storage section 8 and transferred to another transport vehicle (not shown), or the storage section 8 is removed from the airframe 1, and another empty storage area 8 is attached to the airframe 1, etc.

  When the worker carries out the work as described above and the inclination sensor 45 detects that the machine 1 has returned to the horizontal state, the different alarm described above is stopped, and the worker may resume the work. .

(First Embodiment of the Invention)
In the weight position changing unit 40, the front limit position B2 may be disposed on the upper side or the front side of the auxiliary wheel 6 by disposing the guide portion 36 at a slightly higher position or by placing the guide portion 36 obliquely upward. Thereby, the support part 38 and the balance weight 35 move the upper side of the auxiliary wheel 6 to the front side, and reach front limit position B2.

  In the weight position changing unit 40, the front limit position B2 may be disposed on the vehicle body center side (right side) of the auxiliary wheel 6 by disposing the guide portion 36 slightly on the vehicle body center side (right side). As a result, the support portion 38 and the balance weight 35 move forward on the airframe center side (right side) of the auxiliary wheel 6 to reach the front limit position B2.

(Second alternative embodiment of the invention)
If it is configured as described above (the first embodiment of the invention), the distance between the rear limit position B1 and the front limit position B2 becomes large, so the hydraulic cylinder 39 may not be able to cope with it. In this case, it may be configured as follows.

A wire for forward movement (not shown) for moving the support portion 38 and the balance weight 35 from the rear limit position B1 to the front limit position B2, and a return wire for moving the front limit position B2 to the rear limit position B1 (FIG. Not shown).
The forward and backward wires are wound and extended by an electric motor (not shown) (corresponding to an actuator) to drive the support 38 and the balance weight 35 across the rear limit position B1 and the front limit position B2. Move it.

  The present invention is applicable not only to radish harvesters, but also to crop harvesters such as carrot harvesters and onion harvesters.

1 Aircraft 8 Storage Section 11 First Transport Belt (Harvesting Section, Transport Body)
12 Second conveyor belt (harvest unit, conveyor)
35 Balance weight 38 Support part 39 Actuator 40 Weight position change part 45 Inclination sensor A Crop

Claims (3)

The harvesting department, which harvests crops in the field,
A reservoir provided at the rear of the airframe for storing the crop harvested by the harvester;
It is equipped with a balance weight provided at the front of the fuselage, and a tilt sensor that detects the tilt angle of the fuselage in the longitudinal direction.
A crop harvester provided with a weight position changing unit that changes the position of the balance weight with respect to the vehicle body in the front and back direction so that the vehicle body is maintained horizontally in the front and back direction based on the detection value of the tilt sensor. The harvest section
The crop according to claim 1, which is a right and left conveyance body rotationally driven so as to hold the crop on the field from the right and left sides at the front of the fuselage and lift it from the field and transport the crop to the rear side of the fuselage. Harvester. The weight position change unit
A support unit to which the plurality of balance weights are attached, and an actuator for changing the position of the support unit relative to the airframe in the front-rear direction;
The crop harvester according to claim 1 or 2, wherein the number of the balance weights attached to the support is variable.

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