JP6650708B2 - Combine - Google Patents

Description

The present invention includes a threshing device, a grain tank disposed adjacent to the threshing device, and a grain-lifting device that transports the grains collected by the threshing device to the Glen tank, In the grain device, a vertical transport portion extending upward from the lower portion of the threshing device, and extends laterally from the upper end portion of the vertical transport portion and is inserted into an upper portion on one of the front and rear sides of the side wall of the Glen tank, and has a tip portion. A horizontal transport unit that discharges grains from the formed discharge port into the Glen tank,
In the horizontal transport section, the screw section on the proximal end close to the vertical transport section, and on the distal end side far from the vertical transport section, supported by a rotary shaft extended from the screw shaft of the screw section at the distal end side and from the rotary shaft. And a blade that protrudes radially outward and that throws kernels from the discharge port to the other front and rear side inside the Glen tank by rotation.

  Conventionally, as a combine of this type, the blade portion is provided in a state of radially extending in the radial direction on the rotation axis, and the throwing action surface of the blade portion is configured as a plane facing in a direction orthogonal to the rotation axis. (For example, see Patent Document 1).

Japanese Patent Application No. 2005-055137 (FIG. 5)

According to this type of combine, the grains transported to the horizontal transport section are sent out at a high speed along the screw shaft toward the rotation axis at the tip of the casing along with the rotation of the screw section. Then, the grains are thrown in the Glen tank by the blades rotating together with the rotating shaft.
Therefore, the kernel has a speed vector in the direction along the screw axis (for convenience, referred to as “feed speed vector”) at the time when the grain is fed from the screw portion to the rotation region of the blade portion.

  According to the above-described conventional combine, since the throwing action surface of the blade portion is configured as a plane oriented in a direction orthogonal to the rotation axis, the speed vector (for convenience, "feeding speed") applied to the kernel by the throwing action surface The vector is referred to as a direction perpendicular to the throwing action surface, that is, a direction orthogonal to the rotation axis.

The throwing direction of the grains that fly out of the wings is the resultant direction of the two velocity vectors described above.According to the conventional combine, the throwing direction of the grains is such that the throwing direction of the grains is calculated from the direction orthogonal to the rotation axis. It is biased in the direction.
As a result, there is a problem that the thrown kernels are distributed on the side wall facing the side wall of the Glen tank where the lateral conveyance unit is inserted, and the balance is poor.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to solve the above problems and to provide a combine that can throw grains in a Glen tank in a state with less bias.

The features of the present invention include a threshing device, a grain tank disposed adjacent to the threshing device, and a frying device that transports the grains recovered by the threshing device to the Glen tank,
A vertical transport unit extending upward from a lower portion of the threshing device to the fryer, and a laterally extending upper end of the vertical transport unit is inserted into an upper portion of one of front and rear sides of a side wall of the Glen tank, and has a tip. A horizontal transport unit that discharges grains from the discharge port formed in the unit into the Glen tank,
In the horizontal transport section, a screw section on the proximal end close to the vertical transport section, and supported on a rotary shaft extended from the screw shaft of the screw section on the distal end side far from the vertical transport section, and from the rotary shaft. A blade portion projecting outward in the radial direction, and throwing kernels from the discharge port to the other front and rear sides inside the Glen tank by rotation,
An outer peripheral portion of the rotating shaft is provided with a stay portion that supports the blade portion so that the blade portion can be attached and detached,
An angle adjuster that changes an inclination angle of a throwing action surface of the blade is provided across the blade and the stay,
The throwing action surface is located at a position inclined toward the side wall.

According to the present invention, since the throwing action surface of the blade is inclined toward the side wall, the delivery speed vector is also in the direction toward the side wall of the Glen tank.
Therefore, the throwing direction, which is the resultant direction of the feed speed vector and the feed speed vector, can be closer to or along the direction perpendicular to the rotation axis than in the conventional case.
As a result, the thrown grains are prevented from being biased toward the opposite side wall in the Glen tank, and can be stored in a well-balanced distribution state.
In addition, according to the present invention, since the outer peripheral portion of the rotary shaft is provided with the stay portion that supports the blade portion so that it can be attached and detached, only the blade portion can be removed from the rotary shaft. In the first place, the wings are likely to be worn due to continuous contact with the grains during the throwing operation, and maintenance is required. It can be implemented efficiently in space.
In addition, in the case where the abrasion of the blades becomes severe, it can be dealt with only by replacing only the blades while leaving the rotating shaft, and the cost of parts can be reduced.
Furthermore, according to the present invention, when the inclination angle of the throwing action surface is changed, it can be easily implemented by operating the angle adjustment unit.
The case where the inclination angle of the throwing action surface is changed is, for example, a case where the ratio between the sending speed vector and the sending speed vector changes or a case where the throwing direction is intentionally changed. It is listed as.
Incidentally, as an example in which the ratio between the feed speed vector and the feed speed vector changes, a change occurs in specifications such as the type of grain to be thrown, the yield, and the rotation speed of the rotating shaft. Such a case is mentioned.

  In the present invention, it is preferable that the stay portion is located on a side opposite to the throwing action surface with respect to the blade portion.

Further, since the stay portion is located on the side opposite to the throwing action surface with respect to the blade portion, contact of the stay portion itself with the grain can be prevented by the blade portion.
As a result, it is easy to prevent the stay portion from being worn by the grain, and the cost of parts can be further reduced.

In the present invention, a threshing device, a grain tank disposed adjacent to the threshing device, and a grain-lifting device that transports the grains collected by the threshing device to the Glen tank,
A vertical transport unit extending upward from a lower portion of the threshing device to the fryer, and a laterally extending upper end of the vertical transport unit is inserted into an upper portion of one of front and rear sides of a side wall of the Glen tank, and has a tip. A horizontal transport unit that discharges grains from the discharge port formed in the unit into the Glen tank,
In the horizontal transport section, the screw section on the proximal end close to the vertical transport section, and on the distal end side far from the vertical transport section, supported by a rotary shaft extended from the screw shaft of the screw section at the distal end side and from the rotary shaft. A blade that is projected outward in the radial direction, and that throws kernels from the discharge port to the other front and rear sides inside the Glen tank by rotation,
The throwing action surface of the blade is inclined toward the side wall,
An opening through which the kernels can be taken out is provided at a longitudinally intermediate portion of the casing of the horizontal transport section,
It is preferable that a sensor is provided below the opening inside the Glen tank to temporarily receive the kernel taken out from the casing and detect the state of the kernel.

  According to this configuration, a part of the grain fed into the Glen tank through the casing of the horizontal transport unit is taken out from the opening provided at the longitudinal middle portion of the casing, and is temporarily received. The grain state can be detected by the sensor.

Therefore, the state of the kernel can be detected in parallel without stopping the kernel transport using the kernel transport path from the base end side to the distal end side of the casing.
The grain state to be detected includes, for example, a grain yield per unit time, a moisture value, a protein value, and the like, and can be used for collecting harvest amount data, taste data, and the like.

  In addition, the length of the horizontal transport unit is increased by providing the above-described opening and a sensor and the like therebelow, and accordingly, the position of the blade provided on the tip side of the horizontal transport unit also increases the vertical transport position. The blade approaches the side wall farther from the side, and the position of the blade is shifted. However, as described above, since the throwing action surface of the blade portion is inclined toward the side wall side closer to the vertical transport portion, it is possible to prevent the thrown grains from being biased to one side in the Glen tank. And a combine having a higher added value.

In the present invention, before Kiyoko outer diameter of the distal end side casing portion of the blade portion side of the casing of the conveying section is larger than the outer diameter of the proximal housing portion of the screw portion side of the casing, and The outer diameter of the blade portion is larger than the outer diameter of the screw portion,
A chamfered portion is formed at a corner portion of an outer peripheral portion on the screw portion side in the blade portion,
The distal end of the proximal casing portion extends to the inside of the proximal end of the distal casing portion, and the inner diameter side of the blade portion from the chamfered portion is closer to the distal end of the proximal casing portion. Preferably, it is inserted.

  According to this configuration, since the outer diameter of the tip-side casing portion on the blade side in the casing of the horizontal transport portion is set to be larger than the outer diameter of the screw-side proximal end casing in the casing, The internal space of the distal casing portion has a larger capacity per unit length than the internal space of the proximal casing portion, so that the grains fed by the screw portion can be received in the large space with ample room.

In addition, since the outer diameter of the blade portion is formed larger than the outer diameter of the screw portion, a blade portion having a wider throwing action surface is formed in the large diameter space of the front casing portion. can do.
The large throwing surface allows more grains to be thrown, and the large outer diameter of the wings increases the throwing speed at the outer periphery, allowing more powerful kernels to be thrown. Throwing can be performed, and overall throwing performance can be improved.

In addition, a chamfered portion is formed at a corner portion of an outer peripheral portion of the blade portion on the screw portion side, a distal end portion of the proximal end casing portion extends to an inside of a proximal end side of the distal end casing portion, and Since the inner diameter side of the chamfered portion of the blade portion is inserted into the distal end portion of the base side casing portion, even if the blade is arranged at an angle, the blade portion interferes with the distal end portion of the base side casing. A wide blade portion penetrating into the distal end portion of the proximal casing portion can be formed while avoiding the chamfered portion.
Therefore, the grains sent from the screw portion to the tip side casing portion can be more quickly inherited, and more and more strongly can be thrown into the space in the Glen tank.

  In the present invention, it is preferable that the horizontal transport portion is inserted into a front upper portion of a side wall of the Glen tank.

  According to this configuration, since the horizontal transport section is inserted into the upper front portion of the side wall of the Glen tank, the horizontal transport section can be arranged along the front wall of the Glen tank, and can be extended to the rear wall in the Glen tank. The expanding space can be more effectively used as a grain storage space.

It is a right view of a combine. It is a top view of a combine. It is a back view explanatory view of a combine which shows the state of a grain supply apparatus and a Glen tank. It is a left view of the combine which shows the situation of a Glen tank and a screw conveyor. It is explanatory drawing seen from the 2nd horizontal axis center direction which shows the situation of a screw conveyor and a yield measuring device. It is explanatory drawing seen from the 2nd horizontal axis center direction which shows the state of a screw conveyor and a taste measuring device. It is a cross-sectional view of a screw part. It is a cross-sectional view of a blade part. It is a top view of a blade part. It is explanatory drawing of a combine back view of a blade part. It is a schematic plan view which shows the throwing state in a Glen tank. It is explanatory drawing which shows the speed vector which acts on a grain. It is sectional drawing which shows the principal part of the inspection port part of a Glen tank.

One specific embodiment of a combine according to the present invention will be described with reference to the drawings.
FIG. 1 is a side view of an ordinary combine which is an example of a combine, and FIG. 2 is a plan view. The combine includes a body frame 10 in which a plurality of steel materials such as a channel material and a square pipe material are connected. A pair of right and left crawler-type traveling devices 11 is provided at a lower portion of the body frame 10. An engine 15 is mounted on the front side of the right half of the body frame 10, and an operating unit 13 having a cabin configuration is formed on the upper part thereof.

  The operation unit 13 includes a control lever 17 and a monitor 18. A cutting unit 12 is provided at the front of the body frame 10 so as to be able to move up and down freely. At the rear of the body frame 10, a threshing device 14 that throws in all the culms supplied from the cutting unit 12 to thresh. And a grain tank 2 for storing grains supplied from the threshing apparatus 14 by the lifting apparatus 7, and an unloader 16 for discharging the grains stored in the grain tank 2 to the outside.

  The reaping unit 12 is configured to be able to move up and down around the first horizontal axis X1 oriented in the horizontal direction of the body. State. The reaping unit 12 is raked by the pair of left and right dividers 120 for combing the planted grain culm, the scraping reel 121 for rotatably driving the planted grain culm rearward, and the scraping reel 121. A cutting blade device 122 that cuts the planted grain culm, an auger drum 123 that sends the cut grain culm cut by the cutting blade device 122 backward, and a cut grain culm sent from the auger drum 123 to the front end of the threshing device 14. And a feeder 124 for carrying.

The threshing device 14 is configured to thresh the harvested grain culm supplied from the feeder 124 by using the rotating drum 15a.
The Glen tank 2 is arranged on the right rear of the body frame 10 and is located on the right side of the threshing device 14 and on the rear side of the operating unit 13. The hulling device 7 that functions as a supply conduit for supplying grains from the threshing device 14 to the Glen tank 2 is disposed between the threshing device 14 and the Glen tank 2.
The last stage of the grain raising device 7 is configured as a screw conveyor (corresponding to a horizontal conveying unit) 71, and is inserted into the Glen tank 2. Therefore, the grains transported by the grain lifting device 7 are discharged into the Glen tank 2 from the discharge port 71 </ b> A formed at the tip of the screw conveyor 71.

In addition, an inspection port 20 provided with a transparent window 21 is provided on the top plate 2d of the Glen tank 2 so as to be able to confirm the internal grain storage state from the outside, and is swingably opened and closed (see FIG. 2). ).
As shown in FIG. 13, the transparent window portion 21 is configured by attaching a transparent synthetic resin plate 21B to a central opening of a metal frame member 21A, and the frame member 21A is hinged to a top plate portion 21C. It can be opened and closed by attaching to 2d. The lower surfaces of the frame member 21A and the synthetic resin plate 21B are formed flush with the lower surface of the top plate 2d. With this configuration, it is possible to prevent the kernel from hitting the inspection opening 20 and catching the kernel when the kernel is thrown, which will be described later, and is unlikely to hinder the throwing.

As shown in FIG. 3 and FIG. 4, the grain raising device 7 includes a hoisting conveyor (corresponding to a vertical conveying unit) 75 and a screw conveyor (corresponding to a horizontal conveying unit) 71.
A horizontal conveyor 14A mounted on the bottom of the threshing device 14 in the left-right direction is connected to a bucket-type lifting conveyor 75 at the transport end.
The lifting conveyor 75 extends upward, and is a bucket conveyor in which a plurality of buckets 754 are attached at regular intervals on an outer peripheral side of an endless rotating chain 753 wound around a driving sprocket 751 and a driven sprocket 752. It is. The lifting conveyor 75 is connected to the screw conveyor 71 at the transport end.

  The screw conveyor 71 extends laterally from the upper end of the unloading conveyor 75 and is inserted into the upper portion on the front side of the left side wall 2b of the Glen tank 2. The outer peripheral portion has a circular cross-sectional shape (octagonal or other polygonal shape). (Good) casing 72. A screw portion 73 on the base end side near the lifting conveyor 75 and a distal end farther from the lifting conveyor 75 are supported by a rotation shaft 90B extending from the screw shaft 90A of the screw portion 73 and are radially outward from the rotation shaft 90B. And a blade portion 74 for projecting the kernel from the discharge port 71A to the rear side inside the Glen tank 2 by rotation.

  The screw shaft 90A and the rotating shaft 90B are configured to rotate integrally around the second horizontal axis X2. In this embodiment, the rotation direction is set to the left rotation based on the line of sight from the base end to the tip end of the screw shaft 90A along the second horizontal axis X2.

The casing 72 includes a proximal-side casing portion 72A that covers the screw portion 73, and a distal-side casing portion 72B that is formed to have a larger diameter than the proximal-side casing portion 72A and covers the blade portion 74.
The connection point between the proximal-side casing portion 72A and the distal-side casing portion 72B is connected such that the distal-end portion of the proximal-side casing portion 72A extends to the inside of the proximal side of the distal-side casing portion 72B ( 9 and 10).
The distal end of the distal casing 72B is closed by a lid 72Ba that also serves as a bearing for the rotating shaft 90B.

  The casing 72 is provided with a first opening (corresponding to an opening) 76 at an intermediate portion in the longitudinal direction, and a second opening 77 and a third opening (corresponding to a discharge port 71A) 78 at the end. (See FIG. 3).

As shown in FIGS. 3, 5, and 7, the first opening 76 is located at a position closer to the distal end than the center of the base end casing portion 72A, and is closer to the front wall 2a of the Glen tank 2 in the casing circumferential direction. Are open (see FIGS. 5 and 7).
In addition, below the first opening 76, a yield measuring device 3 for measuring the yield of the grain is provided (see FIGS. 3 and 5). It is configured such that it is temporarily stored in the yield measuring container 30 of the yield measuring device 3 and the yield per unit section of the field can be calculated based on the time required until the stored amount reaches a predetermined amount. The yield measuring device 3 is provided with a weight sensor (an example of a sensor) S for detecting a state in which the stored amount is a predetermined amount (an example of a grain state).

The lower edge of the opening edge of the first opening 76 is formed in a curved surface so as not to make a corner. In this embodiment, the round pipe 76a is fixed along the lower edge of the opening edge, and the outer peripheral curved surface of the round pipe 76a is used (see FIGS. 5 and 7).
In the conveyed material of the screw conveyor 71, in addition to grains, branch stalks that could not be removed by the threshing device 14 may be mixed. In some cases, this branch stalk is caught on the lower edge of the first opening 76 with the rotation of the screw shaft 90A, and in order to prevent this, it is effective to form the lower edge into a curved surface. .

As shown in FIGS. 3, 6, and 8, the second opening 77 is formed in the middle portion in the longitudinal direction of the distal end casing portion 72B. Is formed by opening the peripheral portion on the side of the front wall 2a (see FIG. 6).
A punching metal 77a through which grains can freely pass is provided in the entire opening of the second opening 77, and is configured so as to block the branch veins and allow only the grains to fall downward.
A taste measuring device 4 for measuring the taste of the grains is provided below the second opening 77 (see FIGS. 3 and 6). It is configured to be temporarily stored in the taste measuring container 40 of the taste measuring device 4 and to measure a grain component such as water and protein through spectroscopic measurement of the grain.

  As shown in FIGS. 3, 6, and 8 to 10, the third opening 78 extends over substantially the entire length of the distal end casing 72 </ b> B in the longitudinal direction, and extends around the rear wall 2 c of the Glen tank 2 in the casing circumferential direction. The opening is formed (see FIGS. 6, 8, and 11). A blade 74 is exposed to the third opening 78 (see FIGS. 9 to 11), and the kernel is thrown toward the rear wall 2 c of the Glen tank 2 by throwing grains at the throwing action surface 74 a of the blade 74. Can be discharged.

As shown in FIGS. 8 to 10, the blade portion 74 is detachably attached to the rotating shaft 90B via a stay portion 91 provided integrally on the outer peripheral portion of the rotating shaft 90B.
The stay portion 91 is formed of a rectangular metal plate whose long side extends along the longitudinal direction of the rotation shaft 90B. The stay portions 91 are fixed to two locations on the circumferential surface of the rotating shaft 90B separated by 180 degrees in the circumferential direction, with the short sides protruding along the radial direction of the rotating shaft 90B.

Two stud bolts 91A are fixed to the stay portion 91 on the surface facing forward in the rotation direction of the rotation shaft 90B with a space in the long side direction (see FIGS. 8 and 9). By inserting the stud bolt 91A into the insertion hole 74b formed in the blade portion 74 and holding the blade portion 74 between the two nuts 91B, the blade portion 74 can be supported by the stay portion 91.
Note that the blade portion 74 is attached to the stay portion 91 such that the throwing action surface 74a faces forward in the rotation direction of the rotation shaft 90B. Will be on the opposite side.

By changing the screwing position of the nut 91B to the stud bolt 91A, the separation between the stay portion 91 and the blade portion 74 can be adjusted. Further, by changing the screwing positions of the nuts 91B in the two stud bolts 91A, the blade portions 74 can be supported in an inclined posture with respect to the stay portions 91.
In this embodiment, the blade portion 74 is attached so that the throwing action surface 74a is slightly inclined toward the left side wall 2b from the direction directly behind the Glen tank 2.
The stud bolt 91A and the nut 91B constitute an angle adjusting unit K (see FIG. 9).

The blades 74 are attached to the two stays 91 at an angle as described above. As shown in FIG. 10, the blade portion 74 is formed of a substantially rectangular metal plate having a chamfered portion 74c at a corner portion of the outer peripheral portion on the screw portion 73 side.
In a state where the blade portion 74 is attached to the stay portion 91, the outer diameter of the blade portion 74 is larger than the outer diameter of the screw portion 73.
Further, the blade portion (the end of the blade portion 74 on the screw portion 73 side) closer to the inner diameter portion than the chamfered portion 74c is inserted into the distal end portion of the base side casing portion 72A.

Since the above configuration is provided, as shown in FIG. 11, by rotating the screw shaft 90 </ b> A and the rotating shaft 90 </ b> B, the grain is laterally conveyed by the screw portion 73 and the rearward by the blade portion 74. Grain throwing can be performed continuously.
At this time, it can be considered that a velocity vector as shown in FIG. 12 acts on the grain.
That is, the velocity vector V1 (along the direction of the second horizontal axis X2) generated by the lateral conveyance of the screw portion 73 and the velocity vector V2 (along the direction perpendicular to the throwing action surface 74a) caused by the throwing of the blade portion 74. ) Acts, and the throwing direction of the grain is the direction of the velocity vector V3 that is the resultant of the two velocity vectors V1 and V2.

  Therefore, in the combine of this embodiment, the throwing action surface 74a is inclined so as to slightly face the left side wall 2b of the Glen tank 2, so that the velocity vector V3 faces the center of the width of the Glen tank 2, You can throw it in that direction. As a result, the grains can be distributed in the Glen tank 2 in a state where there is little bias.

[Another embodiment]
Hereinafter, other embodiments will be described.

<1> As described in the previous embodiment, the horizontal transport section 71 is not limited to the one that is inserted into the upper part on the front side of the left side wall 2b of the Glen tank 2; It may be inserted in the upper part on the rear side.
When the Glen tank 2 is a combine arranged on the left side of the threshing device 14, the horizontal transport unit 71 is inserted into the right side wall of the Glen tank 2.

<2> The blade portion 74 is not limited to the configuration attached to the rotating shaft 90B via the stay portion 91, but may be directly attached to the rotating shaft 90B, for example.
Further, the shape and dimension setting of the blade portion 74 are not limited to those of the above embodiment, and for example, the shape may be a square or another shape instead of a rectangle. Moreover, the one without the chamfered portion 74c may be used. Regarding the dimension setting, the outer diameter of the blade portion 74 may be the same (or substantially the same) as the outer diameter of the screw portion 73.

<3> The angle adjustment unit K is not limited to the structure described in the above embodiment, and may employ a known posture changing mechanism.
Further, the configuration may be such that the inclination angle of the blade portion 74 cannot be adjusted without providing the angle adjusting portion K itself.

  Note that, as described above, reference numerals are provided for convenience of comparison with the drawings, but the present invention is not limited to the configuration of the accompanying drawings by the entry. Further, it goes without saying that the present invention can be implemented in various modes without departing from the gist of the present invention.

  The combine can be used for a self-contained combine instead of the ordinary combine.

2 Glen tank 2b Left side wall 7 Frying equipment 14 Threshing equipment 71 Screw conveyor (corresponding to a horizontal transport section)
71A Discharge port 72 Casing 72A Base end casing part 72B Distal end casing part 73 Screw part 74 Blade part 74a Throwing action surface 74b Insertion hole 74c Chamfered part 75 Lifting conveyor (corresponding to vertical conveying part)
76 First opening (corresponding to opening)
90A Screw shaft 90B Rotating shaft 91 Stay part K Angle adjusting part S Weight sensor (an example of a sensor)

Claims (5)

A threshing device, a grain tank disposed in a state adjacent to the threshing device, and a grain lifting device that transports the grains collected by the threshing device to the Glen tank,
A vertical transport unit extending upward from a lower portion of the threshing device to the fryer, and a laterally extending upper end of the vertical transport unit is inserted into an upper portion of one of front and rear sides of a side wall of the Glen tank, and has a tip. A horizontal transport unit that discharges grains from the discharge port formed in the unit into the Glen tank,
In the horizontal transport section, the screw section on the proximal end close to the vertical transport section, and on the distal end side far from the vertical transport section, supported by a rotary shaft extended from the screw shaft of the screw section at the distal end side and from the rotary shaft. A blade that is projected outward in the radial direction, and that throws kernels from the discharge port to the other front and rear sides inside the Glen tank by rotation,
An outer peripheral portion of the rotating shaft is provided with a stay portion that supports the blade portion so that the blade portion can be attached and detached,
An angle adjuster that changes an inclination angle of a throwing action surface of the blade is provided across the blade and the stay,
A combine wherein the throwing action surface is inclined toward the side wall.   The combine according to claim 1, wherein the stay portion is located on a side opposite to the throwing action surface with respect to the blade portion. A threshing device, a grain tank disposed in a state adjacent to the threshing device, and a grain lifting device that transports the grains collected by the threshing device to the Glen tank,
A vertical transport unit extending upward from a lower portion of the threshing device to the fryer, and a laterally extending upper end of the vertical transport unit is inserted into an upper portion of one of front and rear sides of a side wall of the Glen tank, and has a tip. A horizontal transport unit that discharges grains from the discharge port formed in the unit into the Glen tank,
In the horizontal transport section, the screw section on the proximal end close to the vertical transport section, and on the distal end side far from the vertical transport section, supported by a rotary shaft extended from the screw shaft of the screw section at the distal end side and from the rotary shaft. A blade that is projected outward in the radial direction, and that throws kernels from the discharge port to the other front and rear sides inside the Glen tank by rotation,
The throwing action surface of the blade is inclined toward the side wall,
An opening through which the kernels can be taken out is provided at a longitudinally intermediate portion of the casing of the horizontal transport section,
A combine provided below the opening inside the Glen tank with a sensor for temporarily receiving a grain taken out of the casing and detecting a grain state. Before Kiyoko conveying portion outer diameter of the distal end side casing portion of the blade portion side of the casing of larger than the outer diameter of the screw portion side of the base end side casing portion of the casing, and the blade portion The outer diameter is larger than the outer diameter of the screw portion,
A chamfered portion is formed at a corner portion of an outer peripheral portion on the screw portion side in the blade portion,
The distal end of the proximal casing portion extends to the inside of the proximal end of the distal casing portion, and the inner diameter side of the blade portion from the chamfered portion is closer to the distal end of the proximal casing portion. The combine according to any one of claims 1 to 3, which has been inserted.   The combine according to any one of claims 1 to 4, wherein the horizontal transport unit is inserted into a front upper portion of a side wall of the Glen tank.

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