JP6650711B2 - Harvester - Google Patents

Description

  The present invention provides, for example, a reaping processing unit that cuts crops such as rice, wheat, soybeans, and corn, and then traverses them toward an intermediate portion in the machine width direction to join the crops. And a feeder that conveys the paper toward the rear of the machine.

  In the ordinary combine as the harvester, the mowing unit is provided with an auger with spiral blades, and after cutting the planted crop with a cutting blade, a bottom plate located below the auger and a vertical plate located on the rear side of the body of the auger. With the back plate in the facing posture, the cropped crop is laterally fed by the auger feeding action while being received, and is conveyed rearward by the feeder (for example, see Patent Document 1).

JP 2012-244924 A

  In the above-described conventional configuration, for example, if the cut crop is not a long culm, and if the amount of the cut crop is not so large, it is possible to appropriately feed the auger laterally and convey the entire quantity backward by the feeder. It is.

  However, for example, when the crop to be harvested is a long culm and the amount of crop to be harvested is large, the lateral feeding action by the auger is not performed well, and the crop stays during the transportation of the auger. As a result, there is a risk that conveyance jams may occur. That is, if a large amount of long culm crops are laterally fed by the auger, the crop may stay in the gap between the auger and the bottom plate or the back plate. Such a crop is not transported in the axial direction of the auger due to friction between the bottom plate and the back plate without being subjected to the traverse action by the auger spiral blades. If the staying crop is a long culm, the crop of the long culm may wrap around the outer periphery of the auger as the auger rotates. In this case, there is a possibility that the crops that have been successively cut and conveyed will accumulate at the wrapping portion, and may become clumped to cause conveyance jam.

  Therefore, it has been desired to be able to satisfactorily feed the cut crop by the auger and deliver it to the feeder irrespective of the type of the crop and the processing amount.

The characteristic configuration of the harvester according to the present invention includes:
A cutting processing unit that cuts the crops and then feeds laterally toward the middle of the machine in the width direction and joins them, and a feeder that conveys the crops laterally fed by the cutting processing unit toward the rear of the machine,
A cutting blade for cutting the crop, an auger with spiral blades for laterally feeding the cut crop, a bottom plate positioned below the auger, and a vertical posture positioned on the rear side of the body of the auger. A cutting frame having a face plate, and a transport guide that is located on the inner surface of the cutting frame and that transports and guides a crop located between the auger and the cutting frame to the feeder side ,
The transport guide is provided in a region of the rear plate closer to an end of the rear plate than the entrance of the feeder in a lateral width direction of a machine body in a state of protruding from the rear plate toward the auger .

  According to the present invention, the crops cut by the cutting blades are received by the cutting frame, are fed sideways by the spiral blades of the auger, and are fed sideways toward the middle part in the machine body width direction to join. Thereafter, the crops that have been fed side by side are delivered to the feeder, and are transported toward the rear of the machine by the feeder. At this time, the crop to be cut is a long culm, and the cut amount is large, and when a large amount of cut crop is carried in, the cut crop is located in the gap between the auger and the cutting frame when being laterally fed by the auger. Crops tend to stay without being traversed by the auger spiral blades.

  As described above, the crop existing in the gap between the auger and the cutting frame is not affected by the traversing action by the spiral blade, but the rotational force along the rotation direction of the auger is caused by the sliding action by the radial outer peripheral end of the spiral blade. The crop rotates with the auger.

  Since the transport guide that acts on the crop located between the auger and the cutting frame is provided, the transport guide acts on the crop that rotates together with the auger as described above, and feeds the crop to the feeder. To the side. As a result, the crop can be prevented from staying in the gap between the auger and the cutting frame, and the cut crop can be favorably fed laterally.

  Therefore, regardless of the type of the crop and the processing amount, the cut crop can be favorably fed sideways by the auger and delivered to the feeder.

The characteristic configuration of the harvester according to the present invention includes:
A cutting processing unit that cuts the crops and then feeds laterally toward the middle of the machine in the width direction and joins them, and a feeder that conveys the crops laterally fed by the cutting processing unit toward the rear of the machine,
A cutting blade for cutting the crop, an auger with spiral blades for laterally feeding the cut crop, a bottom plate positioned below the auger, and a vertical posture positioned on the rear side of the body of the auger. A cutting frame having a face plate, and a transport guide that is located on the inner surface of the cutting frame and that transports and guides a crop located between the auger and the cutting frame to the feeder side,
The reaping unit is connected to the feeder in a state of being deviated to one side in a machine body width direction with respect to the feeder,
The transport guide is provided at a location adjacent to an inlet of the feeder, of a cantilever portion of the reaping processing unit that protrudes in a cantilever shape on one side in a machine width direction than the feeder,
The transport guide is provided in a region extending from the center of the cantilever portion in the machine width direction in the body width direction to the entrance of the feeder .

According to this configuration, the reaping unit is biased to one side in the machine width direction with respect to the feeder, but the crop cut by the reaping unit exists in the entire area of the reaping unit in the machine width direction. The cut crop is then fed by the auger to the feeder entrance. At this time, in the cantilever portion that protrudes in a cantilever shape to one side in the machine lateral width direction from the feeder in the mowing processing unit, all the crops cut in the cantilever portion are fed laterally toward the inlet of the feeder. . At the location adjacent to the feeder entrance, there will be both the crop fed by the auger and the crop cut and sent at that location, and the amount of the crop will be larger than the other parts. .
In such a place where the amount of the crop is large, the stagnation of the crop is likely to occur. Therefore, by providing the transport guide at a position adjacent to the entrance of the feeder, the stagnation of the crop can be efficiently eliminated.
Further, according to this configuration, the transport guide is provided over a wide range of half of the cantilever portion in the lateral width direction of the machine at a location where the amount of crop is likely to be large, so that it is easier to further eliminate the stagnation of the crop. Become.

The characteristic configuration of the harvester according to the present invention includes:
A cutting processing unit that cuts the crops and then feeds laterally toward the middle of the machine in the width direction and joins them, and a feeder that conveys the crops laterally fed by the cutting processing unit toward the rear of the machine,
A cutting blade for cutting the crop, an auger with spiral blades for laterally feeding the cut crop, a bottom plate positioned below the auger, and a vertical posture positioned on the rear side of the body of the auger. A cutting frame having a face plate,
The auger includes a cylindrical drum and a spiral blade that is formed so as to rise radially outward from an outer peripheral portion of the drum, and that is spirally provided in the drum axis direction.
The present invention is characterized in that the spiral blade is provided with an inclined blade portion provided in an inclined posture at a position close to an inlet of the feeder, the free end portion being located on the lower side in the crop feeding direction than the base end portion .

As the spiral blades provided on the outer periphery of the drum rotate, the crop is pushed and moved laterally by the feed surface of the spiral blades. In, the amount of the crop increases, and a part of the crop is discharged radially outward by centrifugal force accompanying the rotation of the auger, which is likely to cause stagnation and winding around the auger. In addition, a portion of the auger corresponding to the inlet of the feeder is provided with a scraping body for laterally feeding and merging crops toward the inside of the feeder. In some cases, the lumps are released to the outside in a lump, and such a lump crop may cause a transportation jam.

Therefore, according to the present configuration, the inclined blade portion is provided at a position near the inlet of the feeder in the spiral blade. Since the free end portion of the inclined blade portion is located on the lower side in the crop feed direction than the base end portion, at a position close to the inlet of the feeder, the crop that is being laterally transported by the feed surface of the spiral blade is transferred. , Can be suppressed by the inclined blade portion, and can be prevented from being radially outwardly released by the centrifugal force.

As a result, the crop is released radially outward due to centrifugal force and stays and wraps around the auger, or a large amount of the crop is released in a lump at the place where the crop is scraped toward the inside of the feeder, and clogging occurs. It is possible to avoid disadvantages such as occurrence.

In the present invention, it is preferable that the inclined blade portion is provided in a range extending from a position deviated in a machine width direction from an entrance of the feeder and in front of the entrance .

If the inclined blades are provided only at positions deviated from the entrance of the feeder in the lateral width direction of the aircraft, the crops transferred to the position corresponding to the entrance of the feeder are discharged at once in a radially outward direction. There is a risk of clogging.

On the other hand, according to the present configuration, the inclined blade portion is provided not only at a position deviated in the machine width direction from the inlet of the feeder, but also in a range extending from that position to the front of the inlet. Even after being transported to the location corresponding to the above, the feeding action by the inclined blades continues, so that the crop is gradually released outward in the radial direction, and the possibility of clogging and the like is reduced. Become.

In the present invention, it is preferable that the transport guide is constituted by a plate member provided over the bottom plate and the back plate, and a plurality of the transport guides are provided at intervals in the machine body width direction.

According to this configuration, the transport guide is configured by the plate member, and is provided over the bottom plate and the back plate of the cutting frame. The bottom plate is formed of a plate positioned substantially below the auger and substantially in the longitudinal direction of the fuselage, and the back plate is formed of a plate positioned vertically behind the auger and positioned behind the fuselage. The connection portion between the bottom plate and the back plate is bent in a substantially L-shape, and a substantially triangular space may be formed between the bottom plate and the back plate in a side view. When such a space is formed, there is a high possibility that the crop will stay.

Therefore, since the conveyance guide formed of the plate member is provided over the bottom plate and the back plate, it is possible to prevent the crop from staying in the space formed at the connection point between the bottom plate and the back plate as described above. In addition, since a plurality of transport guides are provided at intervals in the machine body width direction, the crop feeding action can be exerted in a wide range in the machine body width direction, and the crop can be appropriately transferred in the transverse direction.

In the present invention,
The reaping unit is connected to the feeder in a state of being deviated to one side in a machine body width direction with respect to the feeder,
It is preferable that the transport guide is provided at a position adjacent to an inlet of the feeder in a cantilever portion of the reaping processing unit that protrudes in a cantilever shape on one side in the machine body width direction from the feeder .

According to this configuration, the reaping unit is biased to one side in the machine width direction with respect to the feeder, but the crops cut by the reaping unit exist over the entire area of the reaping unit in the machine width direction. The cut crop is then fed by the auger to the feeder entrance. At this time, in the cantilever portion that protrudes in a cantilever shape to one side in the machine lateral width direction from the feeder in the mowing processing unit, all the crops cut in the cantilever portion are fed laterally toward the inlet of the feeder. . Then, at the location adjacent to the feeder entrance, there is both the crop fed by the auger and the crop cut and fed at that location, and the amount of the crop is larger than the other parts. .

In such a place where the amount of the crop is large, the stagnation of the crop is likely to occur. Therefore, by providing the transport guide at a position adjacent to the entrance of the feeder, the stagnation of the crop can be efficiently eliminated.

It is a whole side view of a combine. It is the whole combine top view. It is a top view of an auger. It is a right view of a cutting processing part. It is a right view of a cutting processing part when a cutting blade is in a high position. It is a top view showing an auger drum. It is a notched top view of an auger. It is a partial vertical side view of a cutting processing part. It is sectional drawing of an inclined blade | wing part. It is sectional drawing of a spiral blade. It is a vertical front view of a cutting processing part. It is a partial exploded perspective view of a reaping processing part. It is a top view of a cutting blade. FIG. 4 is a cross-sectional plan view of the right divider disposition portion. It is a vertical front view of the drive part of a cutting blade. It is a partial top view of a cutting blade. FIG. 17 is a sectional view taken along line XVII-XVII in FIG. 16. It is a top view showing the attachment state of the shock absorber. It is a front view showing the attachment state of the shock absorber.

Hereinafter, an embodiment of a common combine as an example of a harvester according to the present invention will be described with reference to the drawings.
〔overall structure〕
FIGS. 1 and 2 show a conventional combine for harvesting crops such as rice and wheat. This combine harvester transports a harvested crop culm as a crop to be harvested to a front portion of a traveling body equipped with a pair of left and right crawler traveling devices 2 at a lower portion of the body frame 1 and transports the harvested crop rearward. 3 is connected so as to be able to move up and down. Then, the traveling machine body handles and processes the harvested grain culm as a crop conveyed from the mowing and transporting unit 3 on the machine body frame 1 and converts the thresh-processed product obtained by the handling process into kernels and discharge. A threshing device 4 for sorting, a grain tank 5 for storing grains obtained by the threshing device 4, a grain discharging device 6 for discharging the grains stored in the grain tank 5 out of the machine, a pilot Is provided with a driving unit 7 and the like for performing a driving operation while riding. This combine is configured as an all-culm input type in which the root of the planted cereal culm is cut and cut, and the entire cut culm culm is input to the threshing device 4.

  The operating unit 7 is located on the front right side of the fuselage, and the grain tank 5 is located behind the operating unit 7. Further, the threshing device 4 and the grain tank 5 are provided in a state where the threshing device 4 is located on the left side and the grain tank 5 is located on the right side. A driving engine 8 is provided below the driving section 7.

  In this embodiment, when defining the longitudinal direction of the aircraft, it is defined along the traveling direction of the aircraft in the working state, and when defining the lateral direction of the aircraft, defining the left and right as viewed from the aircraft traveling direction. . That is, the direction indicated by the reference numeral (F) in FIGS. 1 and 2 is the front side of the aircraft, and the direction indicated by the reference numeral (B) in FIGS. The direction indicated by reference numeral (L) in FIG. 2 is the left side of the aircraft, and the direction indicated by reference numeral (R) in FIG. 2 is the right side of the aircraft. Therefore, the lateral direction of the machine corresponds to the lateral direction of the machine.

  The harvesting transporting unit 3 sends the harvested grain culm, which is harvested by the harvesting processing unit 9, to the cutting processing unit 9 that harvests the planted grain culm to be harvested as the vehicle travels, to the threshing device 4 on the rear side of the machine body. And a hydraulic cylinder 11 for raising and lowering the mowing and extending over the machine body frame 1 and the feeder 10 is extended and retracted to be supported so as to be able to move up and down around the horizontal axis P1.

  The reaping processing unit 9 is supported by a reaping frame 12 as a frame that supports the entire reaping processing unit 9. A divider 13, a rotating reel 14 for scraping the planted grain culm to be harvested backward, a clipper-shaped cutting blade 15 for cutting and cutting the root side of the planted cereal culm to be harvested, An auger 16 is provided for feeding the harvested culm laterally to the middle side in the left-right direction, collecting the culm, and sending the harvested stem backward.

  As shown in FIG. 2, the left and right width (cutting width) of the cutting processing unit 9 is larger than the distance between the lateral outer ends of the left and right crawler traveling devices 2, in other words, the lateral width of the traveling machine body. The left and right crawler travel devices 2 formed at the cut of the planted crop by the processing unit 9 are largely secured in the left-right direction. Thereby, the possibility of stepping on unharvested crops by the left and right crawler traveling devices 2 during the harvesting operation is reduced.

  As described above, the horizontal width of the reaping unit 9 is larger than the lateral width of the traveling body, but since the operating unit 7 is located on the front right side of the body and the feeder 10 is located on the front left side of the body, the reaping processing is performed. The portion 9 is connected to the feeder 10 in a state where the portion 9 is deviated to one side (right side) in the machine lateral width direction with respect to the feeder 10.

  As shown in FIG. 8, the mowing frame 12 includes a frame support 17 formed by connecting square pipes, angle members having an L-shaped cross section, and the like. A rear plate 19 in a vertical position located on the rear side of the auger 16 with respect to the fuselage, and a pair of side walls 20 located at both ends in the lateral direction of the fuselage. The left and right dividers 13 are provided on the front side of the left and right side walls 20 of the mowing frame 12. As shown in FIG. 11, the portion of the back plate 19 to which the feeder 10 is connected is opened so that the inlet 21 of the feeder 10 communicates with the feeder 10, and the harvested crop can be transported from the auger 16.

  As shown in FIGS. 2 and 8, the clipper-type cutting blade 15 is provided along the left and right side walls 20 along the front end of the bottom plate 18, and rotates around the horizontal axis across the left and right side walls 20. An auger 16 is erected freely.

[Rotating reel]
The rotating reel 14 will be described.
As shown in FIGS. 1 and 2, the rotary reel 14 is provided in a state of being supported by a pair of left and right support arms 22 extending forward from an upper portion on the rear end side of the mowing frame 12. In addition, a reel frame 24 is provided so as to be integrally rotatable at left and right ends of a drive shaft 23 rotatably supported at the distal ends of a pair of support arms 22. Each of the pair of left and right reel frames 24 has a substantially hexagonal shape in a side view. Tine support members 25 are provided in a state of being spanned over the pair of left and right reel frames 24 and positioned one by one on each of the six tops, and each tine support member 25 is provided along its longitudinal direction. A plurality of tines 26 (scraping claws) are attached in a state where they are arranged side by side.

  The reel frame 24 is provided with a posture holding mechanism for holding the posture so that the tine 26 maintains the posture extending downward from the tine support member 25 regardless of the rotation of the rotary reel 14. . This posture holding mechanism has a well-known structure, and its configuration will not be described in detail. However, when the rotating reel 14 rotates, the tine 26 rotates while holding the downward posture to move the planted grain culm backward. It is configured to be able to be scraped.

  A hydraulic cylinder 27 is connected to each of the pair of support arms 22 and the side wall 20, and the pair of hydraulic cylinders 27 causes the pair of support arms 22 to move around the axis P <b> 2 on the rear end side with respect to the cutting frame 12. The rotary reel 14 is supported to be vertically movable by swinging up and down.

[Cutting blade 15]
The cutting blade 15 will be described.
As shown in FIGS. 8 and 17, the cutting blade 15 includes an angle-like base 29 fixed to the connection frame 28 extending back to the front end of the bottom plate 18 over the machine body width direction, A receiving blade 30 attached to the receiving blade 29, a movable blade 31 slidably supported on the receiving blade 30, a knife bar 32 for driving the movable blade 31, and a knife clip 33 for holding the movable blade 31 are provided. ing.

  Power is transmitted from the engine 8 via a drive mechanism described later, and the long knife bar 32 over the entire cutting width is driven to reciprocate at a predetermined pitch, and is connected and fixed to the knife bar 32. The movable blade 31 reciprocates and cooperates with the receiving blade 30 in a fixed state to cut and cut the root of the harvested grain culm.

  As shown in FIG. 13, the movable blade 31 is a member for sending out the harvested grain culm to a middle portion in the machine width direction (a delivery point to the feeder 10), and the movable blade 31 moves in the machine traveling direction with respect to the delivery point to the feeder 10. It includes a right side feed member 34 located on the right side as viewed, and a left side feed member 35 located on the left side.

  As shown in FIG. 16 and FIG. 17, the lateral feed members 34 and 35 on both the left and right sides are long in the lateral direction of the machine body and have upper side sawtooth-like lateral feed action portions 34A and 35A, and connecting portions 34B and 35B. It is composed of one plate. The connecting portions 34B and 35B are connected to the knife bar 32 by bolts 110, and the two lateral feed members 34 and 35 are configured to reciprocate integrally with the knife bar 32 and the movable blade 31. When the connection of the bolt 110 to the knife bar is released, the entire transverse feed members 34 and 35 can be completely removed from the cutting blade 15.

  As shown in FIG. 13, the side-feeding action portion 34A of the right side-feeding member 34 has a sawtooth direction set so as to convey the harvested grain culm toward the feeder 10 side, that is, leftward. The direction of the sawtooth is set so that the lateral feeding action portion 35A in 35 conveys the cut culm to the feeder 10 side, that is, rightward. Therefore, these lateral feed members 34 and 35 reciprocate at a predetermined pitch integrally with the movable blade 31 to feed the cut culm to the center of the machine in the lateral width direction, that is, to a delivery point to the feeder 10. Can be.

  The lateral feed members 34 and 35 on both the left and right sides are connected in an oblique posture that is positioned upward as it goes backward. The angle of inclination with respect to the cutting blade 15 is set to be moderate (about 10 degrees) so as not to hinder the transportation of the cut culm. In addition, the base 29 extends rearward of the fuselage more than the rear end position, thereby enhancing the function of feeding the cut culm.

[Drive mechanism of cutting blade 15]
The drive mechanism of the cutting blade 15 will be described.
As shown in FIGS. 11, 12, 14, and 15, a cutting transmission shaft 37 extending along the lateral width direction of the machine at the rear side of the back plate 19, and rotating power about the horizontal axis is transmitted around the front-rear axis. A power conversion mechanism 38 for converting the power to the power, a relay transmission shaft 39 that rotates in the front-rear direction by the converted power, a swing arm 40 provided at the front end of the relay transmission shaft 39, There is provided a link 41 for linking the moving arm 40 and the knife bar 32.

  The power of the engine 8 is transmitted to the cutting transmission shaft 37 via a transmission mechanism (not shown), and the cutting transmission shaft 37 is driven to rotate around the horizontal axis. Although the power conversion mechanism 38 is a well-known configuration, a detailed configuration thereof will not be described, but the power transmission mechanism 38 converts the one-way rotational motion of the mowing transmission shaft 37 into a reciprocating rotational motion of the relay power shaft 39. 37 and the relay transmission shaft 39 are connected.

  The swing arm 40 is connected and fixed to the front end of the relay transmission shaft 39. The swing arm 40 is rotatably connected to one end of a link 41 via a first bearing member 42. The other end of the link 41 is connected to the movable blade 31 via the second bearing member 43. When the relay transmission shaft 39 reciprocates, the swing arm 40 swings left and right, and the movable blade 31 is driven back and forth in the left and right direction.

  As shown in FIGS. 12 and 14, a support portion 45 is provided which protrudes outward from the right side wall portion 20 in the lateral direction of the fuselage, and an insertion hole 46 formed in the support portion 45 extends through the relay transmission shaft 39. And a relay transmission shaft 39 is rotatably supported by a bearing 48 housed in a bearing holder 47 attached to the front side of the support portion 45.

  A cutting blade guard 49 that protects the cutting blade 15 is provided outside the cutting blade 15 in the machine width direction. The cutting blade guard 49 includes a band-shaped plate member 50 and a round bar member 51. The round bar member 51 is fixed to the rear side of the plate member 50 by welding or the like. The round bar member 51 is a laterally U-shaped member whose front side is open in a side view. On the front side of the cutting blade guard 49, the front end of the plate member 50 is connected to the side wall 20 by bolts. The rear side of the cutting blade guard 49 is bolted to the side surface of the support portion 45 via a bracket 52 connected to the round bar member 51.

[Vibration suppression structure of cutting blade 15]
The cutting blade 15 is provided with a shock absorbing material Q for suppressing the vibration by receiving the movable blade 31 at the end of the moving stroke and absorbing the shock in order to suppress the vibration and noise accompanying the movement of the movable blade 31. .

  As shown in FIGS. 18 and 19, on both sides in the longitudinal direction of the cutting blade 15, a cylindrical support base 55 is fixed to a mounting plate 54 fixed to the base 29, and a bolt is attached to the support base 55. The shock absorbing material Q is fixed in a state of being tightened. The shock absorbing material Q is made of, for example, a shock absorbing gel, a low resilience urethane, or the like. The shock absorber Q is provided at a position where the end of the knife bar 32 collides when the knife bar 32 reaches the squealing end. The shock absorber Q can absorb a shock when the knife bar 32 (movable blade 31) stops moving at the stroke end.

[Change the position of the cutting blade 15]
The mounting position of the cutting blade 15 can be changed to a position higher than a normal position when, for example, a lodging crop is to be harvested.
When the lodging crop is to be harvested, the base 29 of the cutting blade 15 is detached from the connection frame 28 and mounted at a high position. That is, as shown in FIG. 5, the support bracket 56 is attached to each of the left and right side wall portions 20, and the base 29 is attached to the left and right support brackets 56. The mounting surface of the support bracket 56 is formed such that the upper surface is slightly inclined rearward with respect to the mounting surface 28 a of the connection frame 28. By forming in this manner, the ground position of the cutting blade 15 is substantially the same even when the height is changed.

  As the cutting blade 15 is changed to a higher position, the relay transmission shaft 39 for driving, the swing arm 40 and the like also need to be changed to a higher position on the upper side. As shown in FIG. 12, the rear end of the relay transmission shaft 39 is supported by the mowing transmission shaft 37 via the power conversion mechanism 38. The front side of the relay transmission shaft 39 is configured to swing up and down around the axis of the cutting transmission shaft 37 to drive the cutting blade 15 at a high position.

  As shown in FIG. 12, two insertion holes 46 are formed in the support portion 45 that supports the front side of the relay transmission shaft 39 at different positions in the vertical direction. When the cutting blade 15 is at the low position (normal position), the relay transmission shaft 39 is inserted through the lower insertion hole 46, and when the cutting blade 15 is at the high position (the position for the lodging crop), the relay The transmission shaft 39 is inserted through the higher insertion hole 46.

  As shown in FIG. 4, when the relay transmission shaft 39 is inserted through the lower insertion hole 46, a bearing holder 47 is attached to the front side of the support portion 45. The front side of the relay transmission shaft 39 is rotatably supported by a bearing 48 provided in a bearing holder 47.

  As shown in FIG. 5, when the relay transmission shaft 39 is inserted through the higher insertion hole 46, the bearing holder 47 is attached to the front side of the support part 45 via the receiving base 58. The mounting surface of the cradle 58 on which the bearing holder 47 is mounted is formed in a posture in which the upper side is slightly inclined rearward with respect to the front surface of the support portion 45. With this configuration, the attitude of the bearing 48 matches the attitude of the relay transmission shaft 39, and the front side of the relay transmission shaft 39 is rotatably supported by the bearing 48 provided in the bearing holder 47. You.

  The position of the cutting blade guard 49 can be changed in accordance with the position change of the cutting blade 15. That is, with the bolt connection to the front side wall portion 20 of the cutting blade guard 49 loosened, the rear side is rocked to be positioned upward, and the bracket 52 is bolted to a different position of the support portion 45. Can be fixed at a high position.

  When the cutting blade 15 is changed to a higher position in this way, the lower end of the rotary reel 14 can be lowered below the cutting blade 15 in a side view. With such a configuration, for example, even when the planted cereal stalks are laid down in a soft field, the scraping function of the rotating reel 14 is effectively exerted on the laid down stalks. Thus, the mowing operation can be favorably performed by the cutting blade 15 while being scraped by the rotating reel 14.

[Auger 16]
The auger 16 will be described.
As shown in FIGS. 2 and 8, the auger 16 includes a pair of left and right spiral blades that exert a lateral feed function toward the front end of the feeder 10 with forward rotation on the outer periphery of a large-diameter cylindrical drum 59. 60 are provided. There are provided seven bar-shaped scraping bodies 61 which extend and retract from the drum 59 in the lateral width region facing the inlet 21 at the front end of the feeder 10 at different positions in the circumferential direction and the axial direction. In the middle of the right side traverse area, there is provided one scraping body 61 which moves out of the drum 59, and in the middle of the left side traversing area, two scrapes 61 which moves out of the drum 59. Is provided. A total of ten scraping bodies 61 are provided.

  As shown in FIG. 7, cover plates 62 and 63 are fixed inside the drum 59 near both right and left ends, and a pair of intermediate support plates 64 and 65 are fixed inside the drum 59 at intervals. Have been. The rotation support shaft 66 is supported by the right cover plate 62 and the right intermediate support plate 64, the rotation support shaft 66 is connected to the right cover plate 62, and the rotation support shaft 66 is integrally connected to the drum 59. ing.

  A fixed support shaft 68 is connected and fixed to the left side wall portion 20 in a state of being concentric with the rotation support shaft 66. The fixed support shaft 68 is connected to the left side of the drum 59 via a bearing 69 and a bearing bracket 70. The outer cover plate 63 is rotatably fitted to the outside.

  An eccentric support shaft 71 is provided in a state where rotation is fixed to the fixed support shaft 68 by key connection. A scraping body 61 is mounted on the outer peripheral portion of the eccentric support shaft 71 so as to be rotatable around a shaft center P3 along a fixed support shaft 68. Each of the plurality of scraping bodies 61 is configured to be slidably guided on the drum 59 so as to be able to move back and forth. The right and left eccentric support shafts 71 are provided as a pair, and the left and right eccentric support shafts 71 are connected to a left intermediate support plate 65 by a relay shaft 73 supported via a bearing bracket 70.

  When the rotation support shaft 66 is driven to rotate and the drum 59 rotates counterclockwise in FIG. 8, each auger 16 follows the auger 16 and rotates around the axis of the eccentric support shaft 71. At this time, the distance between the eccentric support shaft 71 and the drum 59 changes according to the rotation phase, and each of the scraping bodies 61 rotates while moving out of the drum 59 to move with the bottom plate 18 and the back plate 19. Crops are squeezed into the feeder 10 while avoiding interference.

As shown in FIG. 6, an opening 76a is formed in the drum 59 for an assembling operation and a maintenance operation of the scraping body 61, and the opening 76a is closed by a detachable cover 76b. The opening 76a has four circular openings and one slot-shaped opening.
Of the four circular openings 76 a, the one on the third surface on the right side is for assembling and maintaining a crank-shaped support portion around the relay shaft 72 that supports the pair of left and right eccentric support shafts 71.
FIG. 6 shows a type in which one rotation of the drum 59 is developed so that the structure can be easily understood.

  A triangular transfer plate 74 is provided between the left and right spiral blades 60 in a region where the scraper 61 squeezes the feeder 10 into the inlet 21 and is located between the left and right spiral blades 60. The transport plate 74 is formed to have a lateral width substantially equal to the lateral width of the entrance 21. The transport plate 74 transports the crop to the entrance 21 side.

  The auger 16 has an inclined blade portion 75 provided at a position close to the inlet 21 of the feeder 10 in the spiral blade 60 in such a manner that the free end portion is located on the lower side in the crop feeding direction than the base end portion. . As shown in FIG. 7, the inclined blade portion 75 is provided in a range extending from a position deviated from the inlet 21 of the feeder 10 in the right-hand spiral blade 60 in the lateral width direction of the machine body and forward of the inlet 21. Specifically, it is provided in a region wound about 180 degrees along the outer periphery of the drum 59 from the left end of the right spiral blade 60 toward the right side.

  In the area other than the inclined blade section 75, as shown in FIG. 10, the spiral blade 60 has a 90-degree angle with respect to the outer peripheral surface of the drum 59, but as shown in FIG. The inclined blade portion 75 is joined to the outer peripheral surface of the drum 59 in a state of being inclined inward toward the inlet 21 of the feeder 10 by a predetermined angle α (for example, about 20 degrees) from 90 degrees.

  That is, the transport surface of the inclined blade portion 75 at a portion located in the vicinity of the inlet 21 is inclined so as to be closer to the inlet 21 as it is located radially outward of the drum 59. Thereby, in the region where the transported amount of the cut grain culm increases, the cut grain culm is prevented from jumping outward in the radial direction of the drum 59. As a result, it is difficult for the harvested crop to wrap around the auger 16, and the occurrence of clogging of the auger 16 with the harvested crop can be suitably suppressed. Of the spiral blades 60 on the right side, the inclined blade portion 75 and the spiral blades 60 in other regions are connected by using a sheet metal material or the like.

[Transport guide]
The harvesting frame 12 is provided with a transport guide 77 located on the inner surface thereof for transporting and guiding the harvested grain culm (crop) located between the auger 16 and the harvesting frame 12 to the feeder 10 side. The transport guide 77 is constituted by a plate member provided over the bottom plate 18 and the back plate 19, and is provided with a plurality at intervals in the machine body width direction.

  As shown in FIGS. 2 and 7, the reaper 9 is connected to the feeder 10 in a state where the reaper is biased to the right side of the machine with respect to the feeder 10, and the reaper 9 is cantilevered to the right of the machine with respect to the feeder 10. They are connected in a protruding state. The transport guide 77 is provided at a location adjacent to the inlet 21 of the feeder 10 in a cantilevered portion of the reaper 9 that protrudes to the right of the machine body with respect to the feeder 10. Specifically, as shown in FIG. 7, the transport guide 77 is provided in an area W <b> 1 that extends from the center of the cantilever portion of the reaping unit 9 in the machine width direction to the entrance 21 of the feeder 10.

Next, the configuration of the transport guide 77 will be described.
As shown in FIGS. 8 and 12, the transport guide 77 is provided with three types of guide components 78, 79, and 80 that are vertically divided into three parts while being separated by the upper and lower scrapers 81. I have.

  Although not shown in detail, the upper and lower scrapers 81 exert a scraping action on crops fed by the auger 16 and are provided on both left and right sides of the entrance 21. Each of the scrapers 81 is formed of an L-shaped angle material, and is formed to be long over the width direction.

  As shown in FIGS. 8 and 12, the first guide structure 78 located at the lowermost position is located at a corner where the bottom plate 18 and the back plate 19 are connected, and the bottom plate 18 and The rear plate 19 covers a portion below the lower scraper 81 and a substantially triangular region formed by the outer edge of the auger 16, and the upper side is closer to the right side of the fuselage when viewed from the front of the body. It is provided in a tilted posture.

  The first guide component 78 has a shape obtained by bending a plate body into a substantially L-shape, a transport guide portion 78A that transports and guides the cut culm in the above-described substantially triangular area, the bottom plate 18 and the back plate. 19 and a mounting portion 78 </ b> B for mounting on the mounting portion 19. The mounting portion 78B is connected to the bottom plate 18 and the back plate 19 by fastening bolts.

  The second guide component 79 located at the middle part in the vertical direction covers the area formed by the outer edge of the auger 16 and the portion sandwiched between the upper and lower scrapers 81 of the rear plate 19 when viewed from the side of the fuselage. In addition, when viewed from the front of the machine body, the first guide member 78 is provided in an inclined posture such that the upper side thereof is closer to the right side of the machine body in a state of being connected to the upper side.

  The second guide component 79 has a shape obtained by bending a plate body into a substantially L-shape, and includes a transport guide portion 79A for transporting and guiding the harvested grain culm in the above-described region, and an attaching portion for attaching to the rear plate 19. 79B. The mounting portion 79B is connected to the back plate 19 by fastening bolts.

  The third guide member 80 located in the upper part in the vertical direction covers the upper part of the rear plate 19 above the upper scraper 81 and the area formed by the outer edge of the auger 16 in a side view of the fuselage. In addition, when viewed from the front of the fuselage, the second guide member 79 is provided in an inclined posture such that the upper side thereof is closer to the right side of the fuselage in a state of being connected to the upper side.

  The third guide component 80 has a shape obtained by bending a plate body into a substantially L-shape, and includes a transport guide portion 80A for transporting and guiding the harvested grain culm in the above-described region, and an attaching portion for attaching to the rear plate 19. 80B. The mounting portion 80B is connected to the back plate 19 by fastening bolts.

  A set of transport guides 77 is configured by combining the first guide component 78, the second guide component 79, and the third guide component 80. Then, as shown in FIGS. 7 and 12, three sets of the conveyance guides 77 are spaced from each other in the machine width direction in a region extending from the center of the cantilever portion of the reaper 9 to the inlet 21 of the feeder 10. It is provided open.

  By providing such a conveyance guide 77, it is possible to prevent the cut grain culm from wrapping around the auger 16 and to satisfactorily feed the cut grain at a location adjacent to the inlet of the feeder 10 where the transport amount of the cut grain is increased. it can.

〔feeder〕
As shown in FIG. 1, the feeder 10 includes a pair of left and right endless wheels inside a rectangular tubular feed case 82, over a drive wheel body 83 located on the upper rear side and a driven wheel body 84 located on the lower front side. The rotation chain 85 is wound, and a locking conveyance body (not shown) is provided at predetermined pitches over the pair of left and right endless rotation chains 85. At the front end of the feed case 82, an inlet 21 communicating with the reaper 9 is formed. The rear end of the feed case 82 is connected to the threshing device 4. Then, by rotating the endless rotation chain 85, the harvested crop (cutting culm) delivered from the cutting processing unit 9 is transported to the threshing device 4.

[Another embodiment]
(1) In the above embodiment, the transport guide 77 is provided so as to be located on the right side of the machine body with respect to the feeder 10 in the reaper 9, but the transport guide 77 is also provided on the left side of the machine body with respect to the feeder 10 in the reaper 9. May be provided.

(2) In the above embodiment, the transport guide is configured by a plate member and provided with three at intervals in the machine body width direction. However, the configuration is not limited to three, and the transport guide may be provided with only one. It may be a configuration provided with, or a configuration provided with four or more.

(3) In the above-described embodiment, the transport guide is configured to be divided into three in the up-down direction. However, only the guide located at the lowest position may be configured.

(4) In the above embodiment, the inclined blade section is provided in a range extending from a position deviated from the entrance of the feeder in the lateral width direction of the machine to the front of the entrance. However, instead of this configuration, the inclined blade section is provided with the feeder. May be provided only at a position deviated in the lateral width direction of the fuselage from the entrance of the auger, not limited to only a part, and may be provided with inclined blades over the entire width of the auger.

(5) In the above-described embodiment, an example in which the present invention is applied to an ordinary combine harvester for cutting rice, wheat, and the like has been described. However, the present invention can be applied to other types of harvesters such as a corn harvester.

  INDUSTRIAL APPLICABILITY The present invention is applicable to a harvester such as a normal combine or a corn harvester.

9 Cutting unit 10 Feeder 12 Cutting frame 15 Cutting blade 16 Auger 18 Bottom plate 19 Back plate 21 Inlet 59 Drum 60 Spiral blade 75 Inclined blade unit 77 Transport guide

Claims (6)

A cutting processing unit that cuts the crops and then feeds laterally toward the middle of the machine in the width direction and joins them, and a feeder that conveys the crops laterally fed by the cutting processing unit toward the rear of the machine,
A cutting blade for cutting the crop, an auger with spiral blades for laterally feeding the cut crop, a bottom plate positioned below the auger, and a vertical posture positioned on the rear side of the body of the auger. A cutting frame having a face plate, and a transport guide that is located on the inner surface of the cutting frame and that transports and guides a crop located between the auger and the cutting frame to the feeder side ,
The harvester , wherein the transport guide is provided in a region of the rear plate closer to an end portion in a machine body width direction than an entrance of the feeder, in a state of protruding from the rear plate toward the auger . A cutting processing unit that cuts the crops and then feeds laterally toward the middle of the machine in the width direction and joins them, and a feeder that conveys the crops laterally fed by the cutting processing unit toward the rear of the machine,
A cutting blade for cutting the crop, an auger with spiral blades for laterally feeding the cut crop, a bottom plate positioned below the auger, and a vertical posture positioned on the rear side of the body of the auger. A cutting frame having a face plate, and a transport guide that is located on the inner surface of the cutting frame and that transports and guides a crop located between the auger and the cutting frame to the feeder side ,
The reaping unit is connected to the feeder in a state of being deviated to one side in a machine body width direction with respect to the feeder,
The transport guide is provided at a location adjacent to an inlet of the feeder, of a cantilever portion of the reaping processing unit that protrudes in a cantilever shape on one side in a machine width direction than the feeder ,
The harvester, wherein the transport guide is provided in a region extending from a central portion of the cantilever portion in the body width direction of the mowing unit to an entrance of the feeder . A cutting processing unit that cuts the crops and then feeds laterally toward the middle of the machine in the width direction and joins them, and a feeder that conveys the crops laterally fed by the cutting processing unit toward the rear of the machine,
A cutting blade for cutting the crop, an auger with spiral blades for laterally feeding the cut crop, a bottom plate positioned below the auger, and a vertical posture positioned on the rear side of the body of the auger. a cutting frame having a face plate,
The auger includes a cylindrical drum and a spiral blade that is formed so as to rise radially outward from an outer peripheral portion of the drum, and that is spirally provided in the drum axis direction.
A harvester comprising: an inclined blade portion provided at an inclined position in which a free end portion is located on a lower side in a crop feeding direction than a base end portion, at a position near an inlet of the feeder in the spiral blade . 4. The harvester according to claim 3 , wherein the inclined blade portion is provided in a range extending from a position deviated in a machine body width direction from an entrance of the feeder and in front of the entrance. The conveyance guide, the conjunction is constituted by a bottom plate and a plate member provided over said backplate, harvesting machine according to claim 1 or 2, wherein are provided a plurality at intervals in the machine body lateral width direction. The reaping unit is connected to the feeder in a state of being deviated to one side in a machine body width direction with respect to the feeder,
The conveyance guide of the cantilevered portion projecting like a cantilever on one side vehicle body width direction than the feeder in the cutting processing unit, according to claim 1 or 5 is provided at a position adjacent to the inlet of the feeder A harvester according to claim 1.

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