JP2022150419A - Threshing device - Google Patents

Abstract

To provide a threshing device that discharges the foreign substance such as sand or dust coming down into a transfer shelf of a swinging sorter from a threshing chamber to the outside, and reduces the contact frequency between the grain and the foreign substance, and thereby enables preventing the grain skin from being damaged.SOLUTION: A swinging sorter (21) is provided in the upper part of a sorting chamber (20). The upper part of the swinging sorter (21) is formed of a transfer shelf (22) comprising a plate-like member and a grain sieve (24) comprising multiple sieves. Multiple first opening (50) or second opening (51) are provided in the transfer shelf (22). A rear part of a discharge guide (27) comprising the plate-like member is fixed in the lower surface of the transfer shelf (22). The discharge guide (27) is extended toward the front lower side.SELECTED DRAWING: Figure 4

Description

The present invention relates to a threshing apparatus equipped with an oscillating sorter.

Conventionally, in order to improve the quality of grains that have been threshed and sorted, a plurality of plate-shaped sieves are provided at predetermined intervals in the horizontal direction on the upper part of the rocking sorting device and the grain pan of the rocking sorting device. is proposed. (Patent document 1)

In order to suppress the leakage of contaminants such as straw waste mixed in with the grains that have leaked down to the swinging sorting device, a sorting net woven in a grid pattern is provided at the top of the swinging sorting device, and the swinging A technology has been proposed in which a plurality of plate-shaped sieves are provided in a grain pan of a sorting apparatus at predetermined intervals in the left-right direction. (Patent Document 2)

JP-A-2006-81524 JP-A-2018-85958

However, in the techniques of Patent Documents 1 and 2, grains leaking from the handling chamber to the transfer shelf of the swing sorting device come into contact with impurities such as sand and dust, and the skin of the grains is damaged. There was a fear that the commercial value of the grain would decline.

Therefore, an object of the present invention is to reduce the frequency of contact between grains and impurities by discharging foreign matter such as sand and dust leaking from the handling chamber to the transfer rack of the swing sorting device to the outside. To provide a threshing device capable of suppressing damage to the skin of grains.

The present invention, which has solved the above problems, is as follows.
In the invention according to claim 1, a sorting chamber (20) for sorting and treating the treated material leaking from the threshing chamber (10) is provided below the threshing chamber (10) for threshing the culms. In a threshing device,
An oscillating sorting device (21) is provided in the upper part of the sorting chamber (20), and the upper part of the oscillating sorting device (21) is provided with a transfer shelf (22) made of a plate and a grain sieve (24) made of a plurality of sieves. ), the transfer shelf (22) is provided with a plurality of first openings (50) or second openings (51), and a discharge guide (27) made of a plate-like body is provided on the lower surface of the transfer shelf (22). ) is fixed, and the discharge guide (27) extends forward and downward.

In the invention according to claim 2, a left shifting plate (26A) made of a plate-like body extending rearward and rightward is provided on the left part of the upper surface of the transfer shelf (22), and the upper surface of the transfer shelf (22) is A right-handling plate (26B) made of a plate-like body extending rearward and leftward is provided on the right side, and in plan view, is located forward and leftward from the rear portion of the discharge guide (27) on the upper surface of the transfer shelf (22). The long axis of the provided first opening (50A) or second opening (51A) is provided parallel to the left shift plate (26A), and the first opening (50B) or second opening provided on the front right side The threshing device according to claim 1, wherein the major axis of the portion (51B) is parallel to the right-handing plate (26B).

In the invention according to claim 3, in plan view, the first opening (50C) or the second opening is provided on the upper surface of the transfer shelf (22) on the rear left side of the rear portion of the discharge guide (27). The long axis of (51C) is perpendicular to the left shift plate (26A), and the long axis of the first opening (50D) or the second opening (51D) provided on the rear right side is the right shift plate (26B). 3. The threshing device according to claim 2, which is provided orthogonally to .

In the left side view, the invention according to claim 4 comprises a flat portion (40) extending in the front-rear direction of the transfer shelf (22), and a flat portion (40) extending rearward and upward from the rear end portion of the flat portion (40). and a vertical surface portion (42) extending downward from the rear end of the inclined surface portion (41). ), the threshing apparatus according to any one of claims 1 to 3.

In the left side view, the invention according to claim 5 comprises a flat portion (40) extending in the front-rear direction of the transfer shelf (22), and a flat portion (40) extending rearward and upward from the rear end portion of the flat portion (40). and a vertical surface portion (42) extending downward from the rear end of the slope portion (41). ), the threshing apparatus according to any one of claims 1 to 3.

The invention according to claim 6 is the threshing apparatus according to claim 4 or 5, wherein the vertical surface part (42) is provided with a third opening (52).

The invention according to claim 7 is the threshing apparatus according to any one of claims 1 to 6, wherein the rear part of the discharge guide (27) is fixed to the rear part of the lower surface of the transfer shelf (22).

According to the first aspect of the invention, the oscillating sorting device (21) is provided in the upper part of the sorting chamber (20), and the upper part of the oscillating sorting device (21) serves as the transfer rack (22) made of a plate-like body. A plurality of first openings (50) or second openings (51) are provided in the transfer shelf (22), and a plate-like body is provided on the lower surface of the transfer shelf (22). The rear part of the discharge guide (27) made of By discharging to the outside of the chamber (20), it is possible to reduce the frequency of contact between the grains and foreign matter, thereby suppressing damage to the skin of the grains.

According to the invention of claim 2, in addition to the effect of the invention of claim 1, the left shift plate (26A) made of a plate-like body extending rearward and rightward on the left part of the upper surface of the transfer shelf (22) ) is provided on the right side of the upper surface of the transfer shelf (22), and a right shifting plate (26B) made of a plate-like body extending rearward and leftward is provided on the upper surface of the transfer shelf (22). The long axis of the first opening (50A) or the second opening (51A) provided on the front left side of the rear part of (27) is provided parallel to the left shift plate (26A), and is provided on the front right side Since the long axis of the first opening (50B) or the second opening (51B) is provided parallel to the right-handling plate (26B), contaminants transported along the left-handling plate (26A) and the right-handling plate (26B) are removed. Objects can be efficiently discharged to the outside of the sorting chamber (20).

According to the invention of claim 3, in addition to the effect of the invention of claim 2, in plan view, the discharge guide (27) is provided on the upper surface of the transfer shelf (22) on the rear left side of the rear side of the discharge guide (27). The long axis of the first opening (50C) or the second opening (51C) is provided perpendicular to the left shift plate (26A), and the first opening (50D) or the second opening provided on the rear right side Since the major axis of the part (51D) is provided perpendicular to the right shifter plate (26B), the culms with grains transported along the left shifter plate (26A) and the right shifter plate (26B) are thereby placed in the first direction. 1 opening (50C) or the like can be suppressed and efficiently transferred to the grain sieve (24).

According to the invention of claim 4, in addition to the effects of the invention of any one of claims 1 to 3, in a left side view, the flat portion ( 40), a slant portion (41) extending rearward and upward from the rear end of the flat portion (40), and a vertical surface portion (41) extending downward from the rear end of the slant portion (41). 42), and the first opening (50) is provided in the plane portion (40), so that the contaminants that have leaked into the transfer shelf (22) can be efficiently discharged to the outside of the sorting chamber (20). can be done.

According to the invention of claim 5, in addition to the effect of the invention of any one of claims 1 to 3, in a left side view, the flat portion ( 40), a slant portion (41) extending rearward and upward from the rear end of the flat portion (40), and a vertical surface portion (41) extending downward from the rear end of the slant portion (41). 42), and the second opening (51) is provided on the slope (41), so that the contaminants that have leaked down to the transfer shelf (22) can be efficiently discharged to the outside of the sorting chamber (20). can be done.

According to the invention of claim 6, in addition to the effects of the invention of claim 4 or 5, since the third opening (52) is provided in the vertical surface (42), leakage to the transfer shelf (22) is prevented. Contaminants that have been dropped can be discharged more efficiently to the outside of the sorting chamber (20).

According to the seventh aspect of the invention, in addition to the effects of any one of the first to sixth aspects, the rear portion of the discharge guide (27) is fixed to the rear portion of the lower surface of the transfer shelf (22). Therefore, the contaminants that have leaked down to the transfer shelf (22) can be more efficiently discharged to the outside of the sorting chamber (20).

It is a front view of a combine. It is a left view of a combine. It is a top view of a combine. BRIEF DESCRIPTION OF THE DRAWINGS It is a longitudinal cross-sectional view of the threshing apparatus of 1st Embodiment of the front-back direction. It is a top view of a rocking|swiveling sorting device. (a) is a plan view of a slit in the plane portion of the transfer shelf, and (b) is a left side view of the transfer shelf. FIG. 11 is a plan view of another slit in the plane portion of the transfer shelf; FIG. 11 is a plan view of still another slit in the plane portion of the transfer shelf; (a) is a plan view of a slit in the slope portion of the transfer shelf, and (b) is a left side view of the transfer shelf. FIG. 11 is a plan view of another slit in the slope portion of the transfer shelf; FIG. 11 is a plan view of still another slit in the slope portion of the transfer shelf; (a) is a plan view of a slit in the vertical surface portion of the transfer shelf, (b) is a rear view of the slit in the vertical surface portion, and (c) is a left side view of the transfer shelf. (a) is a plan view of another slit in the vertical surface portion of the transfer shelf, and (b) is a rear view of another slit in the vertical surface portion. (a) is a plan view of still another slit in the vertical surface portion of the transfer shelf, and (b) is a rear view of still another slit in the vertical surface portion. It is the longitudinal cross-sectional view of the front-back direction of the threshing apparatus of 2nd Embodiment.

As shown in FIGS. 1 to 3, the general-purpose combine harvester is provided with a traveling device 2 consisting of a pair of left and right crawlers that travels on the soil surface on the lower side of the body frame 1, and harvests grain stalks in the field on the front side of the body frame 1. A threshing device 4 for threshing and sorting the harvested culms is provided on the rear left side of the pre-harvesting processing device 3, and an operator rides on the rear right side of the pre-harvesting processing device 3. A control section 5 is provided for controlling.

An engine room 6 in which an engine is installed is provided on the lower side of the control unit 5, and a grain tank 7 for storing threshed and sorted grains is provided on the rear side of the control unit 5. A discharge auger 8 is provided for discharging grains to the outside.

The pre-harvesting treatment device 3 includes a conveying device 3A that raises the grain culm in the field and conveys it to the rear side, a cutting blade device 3B that cuts the base of the grain culm conveyed to the rear lower part of the conveying device 3A, It is composed of an auger device 3C that collects the grain culms conveyed to the rear side of the conveying device 3A to the left side, and a feeder house 3D that conveys the collected grain culms to the threshing device 4.

<Threshing device of the first embodiment>
As shown in FIG. 4, the threshing apparatus 4 of the first embodiment comprises a threshing chamber 10 for threshing stalks and a sorting chamber 20 for sorting threshed grains.

On the front and rear walls of the threshing chamber 10, a threshing drum 11 for threshing the stalks conveyed from the feeder house 3D is installed. A receiving net 12 formed in a semicircular arc shape is provided. The upper part of the handling cylinder 11 is covered with an openable and closable handling cylinder cover (not shown), and a dust feed plate for guiding the culms to the rear part of the handling chamber 10 is provided on the inner periphery of the handling cylinder cover. is provided.

At the upper part of the sorting chamber 20, a rocking sorting device 21 for sorting the grains leaking from the handling chamber 10 is provided.

As shown in FIG. 5, above the swing sorting device 21, a transfer shelf 22 formed of a plate-like body is arranged in parallel from the front side at a predetermined interval in the left-right direction and extends in the front-rear direction. A sieve body 23 formed of round steel, a grain sieve 24 formed of a plurality of sieves arranged side by side at predetermined intervals in the front-rear direction and inclined in the vertical direction and extending in the left-right direction, and a predetermined length in the left-right direction. A straw sieve 25 is provided which is formed of a plurality of sieves extending in the front-rear direction and arranged side by side at intervals of . In addition, the inclination angle (opening degree) of the grain sieve 24 can be changed by operating a lever provided on the control section 5 depending on the type of culm to be harvested. As a result, the sorting efficiency can be maintained at a high level regardless of the type of harvested culms.

On the left side of the transfer shelf 22, a left shifting plate 26A that guides the grain stalks and the like conveyed to the transfer shelf 22 to the central portion in the left-right direction is provided and extends toward the rear right side. is provided with a right shifting plate 26B extending rearward and leftward for guiding the culms and the like conveyed to the transfer shelf 22 to the central portion in the left-right direction. In this specification, the left gathering plate 26A and the right gathering plate 26B are collectively referred to as the gathering plate 26. As shown in FIG.

As shown in FIG. 4 , a discharge guide 27 is provided on the lower side of the transfer shelf 22 and extends forward and downward from the intermediate portion of the transfer shelf 22 in the front-rear direction. The length of the ejection guide 27 in the left-right direction is the same as the length of the transfer rack 22 in the left-right direction, and the ejection guide 27 extends from the intermediate portion of the transfer rack 22 in the front-rear direction through the upper side of the winnow 30 to reach the winnow cover 30A. up to the upper front of the As a result, dust such as sand and dust leaked from the slits 50 formed in the transfer shelf 22 can be discharged to the outside of the sorting chamber 20 .

A bucket-shaped grain pan 28 is provided at the bottom of the rocking sorting device 21 to receive grains and the like leaking down from the top.

Below the swing sorting device 21, in order from the front side, a winnow 30 for blowing the sorting air to the swing sorting device 21, a wind splitter 31 for changing the blowing direction of the sorting wind behind the winnow 30, and a swing The first spiral 32 conveys the grains leaking from the sorting device 21 to the grain tank 7, and the swinging sorting device removes the grains with branch stems etc. A number 2 helix 33 is provided for re-conveying to the sorting rack in front of 21 .

(Slits in the flat part of the transfer shelf)
As shown in FIG. 6, in a left side view, the transfer shelf 22 includes a flat portion 40 extending horizontally in the front-rear direction, a slope portion 41 extending rearward and upward from the rear end portion of the flat portion 40, and a slope It is formed of a vertical surface portion 42 extending downwardly from the rear end of portion 41 .

A flat portion 40 positioned on the front left side of the transfer shelf 22 is formed with a left slit 50A having a long axis extending substantially parallel to the left gathering plate 26A. is formed with a right slit 50B having a long axis extending substantially parallel to the right gathering plate 26B. As a result, dust such as sand and dust transferred along the left-handed plate 26A of the transfer shelf 22 is efficiently leaked from the left slit 50A, and the sand and dust transferred along the right-handed plate 26B of the transfer shelf 22 are discharged. Dust such as dust is efficiently leaked from the right slit 50B to reduce the frequency of contact of grains of soybeans and mung beans with dust such as sand and dust, thereby suppressing damage to soft skins of the grains. be able to. The upper portion of the discharge guide 27 is fixed to a portion of the lower surface of the transfer shelf 22 facing the second vertical surface portion 42 from the front side.

A flat portion 40 positioned on the front left side of the transfer shelf 22 is formed with a left slit 50C having a long axis extending substantially orthogonally to the left shifting plate 26A. is formed with a right slit 50D having a parallel long axis extending substantially orthogonally to the right gathering plate 26B. As a result, the culms transferred along the left shifting plate 26A of the transfer shelf 22 are prevented from leaking from the left slit 50C, and the stalks transferred along the right shifting plate 26B of the transfer shelf 22 are prevented from falling to the right. It is possible to prevent leakage from the slit 50D. In addition, since the sorting wind from the winnow 30 is blown to the upper surface of the transfer rack 22 through the slits 50C and 50D, the culms on the transfer rack 22 can be efficiently transferred to the sieve 23 and grain sieve 24. The left slit 50C and the right slit 50D can be formed in the same shape as the left slit 50A and the right slit 50B, respectively. Thereby, the slits 50A to 50D can be easily formed in the plane portion 40. FIG.

In this specification, the left slit 50A, the right slit 50B, the left slit 50C, and the right slit 50D are collectively referred to as the slit 50 (“first opening” in the claims). Moreover, the slit 50 may be formed together with a slit 51 or a slit 52, which will be described later, or may be formed independently.

FIG. 7 illustrates the left half of transfer shelf 22 . As shown in FIG. 7, a left slit 50A having a long axis extending in the front-rear direction is formed in the plane portion 40 positioned on the front left side of the transfer shelf 22, and positioned on the rear left side of the transfer shelf 22. As shown in FIG. It is also possible to form a left slit 50C having a long axis extending in the front-rear direction in the flat portion 40 . Similarly, a right slit 50B having a long axis extending in the front-rear direction is formed in the flat portion 40 located on the right front side of the transfer shelf 22, and the flat portion 40 located on the right rear side of the transfer shelf 22 is formed. It is also possible to form a right slit 50D having a long axis extending along the front-rear direction. Thereby, the slit 50 can be easily formed in the plane portion 40 . In addition, dust such as sand, dust, etc., which is transferred through the middle portion of the transfer shelf 22 in the left-right direction is efficiently leaked from the left slit 50A and the right slit 50B, and the middle portion in the left-right direction of the transfer shelf 22 is moved back and forth. It is possible to prevent the culms transferred at a predetermined angle from leaking down from the left slit 50C and the right slit 50D.

FIG. 8 illustrates the left half of transfer shelf 22 . As shown in FIG. 8, a left slit 50A having a long axis extending in the left-right direction is formed in the plane portion 40 positioned on the front left side of the transfer shelf 22, and positioned on the rear left side of the transfer shelf 22. It is also possible to form a left slit 50C having a long axis extending in the left-right direction in the flat portion 40. Similarly, a right slit 50B having a long axis extending in the left-right direction is formed in the plane portion 40 located on the front right side of the transfer shelf 22, and the plane portion 40 located on the rear right side of the transfer shelf 22 is formed. It is also possible to form a right slit 50D having a long axis extending in the left-right direction. Thereby, the slit 50 can be easily formed in the plane portion 40 . In addition, dust such as sand, dust, etc., which is transferred through the middle portion of the transfer shelf 22 in the left-right direction is efficiently leaked from the left slit 50A and the right slit 50B, and the middle portion in the left-right direction of the transfer shelf 22 is moved back and forth. It is possible to prevent the culms transferred at a predetermined angle from leaking down from the left slit 50C and the right slit 50D.

(Slit on the slope of the transfer rack)
As shown in FIG. 9, a left slit 51A having a long axis extending substantially parallel to the left shifting plate 26A is formed in the inclined surface portion 41 located on the front left side of the transfer shelf 22, and the front right side of the transfer shelf 22 is formed. A right slit 51B having a long axis extending substantially parallel to the right gathering plate 26B is formed in the slope portion 41 located at the bottom. As a result, the length of the slope portion 41 in the front-rear direction is generally longer than the length of the flat portion 40 in the front-rear direction. Dust such as sand and dust that are transferred along the right shifting plate 26B of the transfer shelf 22 are efficiently leaked from the right slit 51B, so that soybeans and mung beans are efficiently leaked from the left slit 51A. It is possible to reduce the frequency of the grains coming into contact with dust such as sand and dust, and to further suppress damage to the soft outer skin of the grains. The upper portion of the discharge guide 27 is fixed to a portion of the lower surface of the transfer shelf 22 facing the second vertical surface portion 42 from the front side.

A left slit 51C having a long axis extending substantially orthogonally to the left shifting plate 26A is formed on the slant portion 41 positioned on the front left portion of the transfer shelf 22, and the slant portion 41 positioned on the front right portion of the transfer shelf 22 is formed. is formed with a right slit 51D having a parallel long axis extending substantially perpendicularly to the right gathering plate 26B. As a result, the culms transferred along the left shifting plate 26A of the transfer shelf 22 are prevented from leaking from the left slit 51C, and the stalks transferred along the right shifting plate 26B of the transfer shelf 22 are prevented from falling to the right. It is possible to prevent leakage from the slit 51D. In addition, since the sorting wind from the winnow 30 is blown to the upper surface of the transfer rack 22 through the slits 51C and 51D, the culms on the transfer rack 22 can be efficiently transferred to the sieve 23 and grain sieve 24. The left slit 51C and the right slit 51D can also be formed in the same shape as the left slit 51A and the right slit 51B, respectively. Thereby, the slits 51A to 51D can be easily formed in the slope portion 41. As shown in FIG.

In this specification, the left slit 51A, the right slit 51B, the left slit 51C, and the right slit 51D are collectively referred to as the slit 51 (“second opening” in the claims). Also, the slit 51 may be formed together with the slit 50 or a slit 52 described later, or may be formed independently.

FIG. 10 illustrates the left half of transfer shelf 22 . As shown in FIG. 10, a left slit 51A having a long axis extending in the front-rear direction is formed in the sloped portion 41 positioned on the front left side of the transfer shelf 22, and positioned on the rear left side of the transfer shelf 22. As shown in FIG. A left slit 51C having a long axis extending in the front-rear direction can also be formed in the inclined surface portion 41. Similarly, a right slit 51B having a long axis extending in the front-rear direction is formed in the sloped portion 41 located on the front right side of the transfer shelf 22, and the sloped portion 41 located on the rear right side of the transfer shelf 22 is formed. It is also possible to form a right slit 51D having a long axis extending along the front-rear direction. Thereby, the slit 51 can be easily formed in the slope portion 41 . In addition, dust such as sand, dust, etc., which is transferred through the intermediate portion of the transfer shelf 22 in the lateral direction is efficiently leaked from the left slit 51A and the right slit 51B, and the intermediate portion of the transfer shelf 22 in the lateral direction is moved forward and backward. It is possible to prevent the culms transferred at a predetermined angle from leaking down from the left slit 51C and the right slit 51D.

FIG. 11 illustrates the left half of transfer shelf 22 . As shown in FIG. 11, a left slit 51A having a long axis extending in the left-right direction is formed in the sloped portion 41 positioned on the front left side of the transfer shelf 22, and positioned on the rear left side of the transfer shelf 22. As shown in FIG. It is also possible to form a left slit 51C having a long axis extending in the left-right direction in the inclined surface portion 41. Similarly, a right slit 51B having a long axis extending in the left-right direction is formed in the slope portion 41 located on the front right side of the transfer shelf 22, and the slope portion 41 located on the rear right side of the transfer shelf 22 is formed. It is also possible to form a right slit 51D having a long axis extending in the left-right direction. Thereby, the slit 51 can be easily formed in the slope portion 41 . In addition, dust such as sand, dust, etc., which is transferred through the intermediate portion of the transfer shelf 22 in the lateral direction is efficiently leaked from the left slit 51A and the right slit 51B, and the intermediate portion of the transfer shelf 22 in the lateral direction is moved forward and backward. It is possible to prevent the culms transferred at a predetermined angle from leaking down from the left slit 51C and the right slit 51D.

(Slit in the vertical surface of the transfer shelf)
FIG. 12 illustrates the left half of transfer shelf 22 . As shown in FIG. 12, the vertical surface portion 42 of the transfer shelf 22 is formed with a slit 52 (a "third opening" in the claims) having a long axis extending at a predetermined angle with respect to the vertical direction. there is As a result, dust such as sand and dust transferred to the flat portion 40 of the transfer shelf 22 is efficiently leaked from the slits 52 to prevent it from staying at the corners of the flat portion 40 and the vertical surface portion 42, so that the soybeans can be transported. It is possible to reduce the frequency of contact of mung bean kernels with dust such as sand and dust, thereby suppressing damage to the soft outer skin of the kernels. In addition, the culms transferred to the flat portion 40 are prevented from leaking through the slits 52, and transferred to the sieve 23 and the grain sieve 24 at the rear to maintain high grain recovery efficiency. The slits 52 may be formed together with the slits 50 and 51, or may be formed independently.

FIG. 13 illustrates the left half of transfer shelf 22 . As shown in FIG. 13, the vertical surface portion 42 of the transfer shelf 22 is formed with a slit 52 having a longitudinal axis extending along the vertical direction. Thereby, the slit 52 can be easily formed in the vertical surface portion 42 .

FIG. 14 illustrates the left half of transfer shelf 22 . As shown in FIG. 14, the vertical surface portion 42 of the transfer shelf 22 is formed with a slit 52 having a long axis extending in the left-right direction. Thereby, the slit 52 can be easily formed in the vertical surface portion 42 .

<Threshing device of the second embodiment>
FIG. 15 shows the threshing device 4 of the second embodiment. The same reference numerals are assigned to the same members, and the description thereof is omitted.

A discharge guide 27 is provided on the lower side of the transfer shelf 22 and extends forward and downward from the rear end portion of the transfer shelf 22 in the front-rear direction. The length of the ejection guide 27 in the left-right direction is the same as the length of the transfer rack 22 in the left-right direction, and the ejection guide 27 extends from the intermediate portion of the transfer rack 22 in the front-rear direction through the upper side of the winnow 30 to reach the winnow cover 30A. up to the upper front of the As a result, all the dust such as sand and dust leaked from the slits 50 formed in the transfer shelf 22 can be discharged to the outside of the sorting chamber 20 . As described above, the flat surface portion 40 of the transfer shelf 22 is formed with the slit 50 , the inclined surface portion 41 is formed with the slit 51 , and the vertical surface portion 42 is formed with the slit 52 .

10 Handling chamber 20 Sorting chamber 21 Swing sorting device 22 Transfer shelf 24 Glen sieve 26A Left gathering plate 26B Right gathering plate 27 Discharge guide 40 Plane portion 41 Slope portion 42 Vertical surface portion 50 Slit (first opening)
51 slit (second opening)
52 slit (third opening)

The present invention relates to a threshing apparatus equipped with an oscillating sorter.

Conventionally, in order to improve the quality of grains that have been threshed and sorted, a plurality of plate-shaped sieves are provided at predetermined intervals in the horizontal direction on the upper part of the rocking sorting device and the grain pan of the rocking sorting device. is proposed. (Patent Document 1)

In order to suppress the leakage of contaminants such as straw waste mixed in with the grains that have leaked down to the swinging sorting device, a sorting net woven in a grid pattern is provided at the top of the swinging sorting device, and the swinging A technology has been proposed in which a plurality of plate-shaped sieves are provided in a grain pan of a sorting apparatus at predetermined intervals in the left-right direction. (Patent Document 2)

JP-A-2006-81524 JP-A-2018-85958

However, in the techniques of Patent Documents 1 and 2, grains leaking from the handling chamber to the transfer shelf of the swing sorting device come into contact with impurities such as sand and dust, and the skin of the grains is damaged. There was a fear that the commercial value of the grain would decline.

Therefore, an object of the present invention is to reduce the frequency of contact between grains and impurities by discharging foreign matter such as sand and dust leaking from the handling chamber to the transfer rack of the swing sorting device to the outside. To provide a threshing device capable of suppressing damage to the skin of grains.

The present invention, which has solved the above problems, is as follows.
In the invention according to claim 1, a sorting chamber (20) for sorting and treating the treated material leaking from the threshing chamber (10) is provided below the threshing chamber (10) for threshing the culms. In a threshing device,
A rocking sorting device (21) is provided in the upper part of the sorting chamber (20),
The upper part of the rocking sorting device (21) is formed by a plate-like transfer shelf (22) and a grain sieve (24) consisting of a plurality of sieves. An extending flat portion (40), a slant portion (41) extending rearward and upward from the rear end of the flat portion (40), and downward from the rear end of the slant portion (41). a plurality of first openings (50) in said plane portion (40) and a plurality of second openings (51) in said slope portion (41). a rear part of a discharge guide (27) made of a plate-like body is fixed to the lower surface of the transfer shelf (22), the discharge guide (27) extends forward and downward, and the transfer shelf (22) A left shift plate (26A) consisting of a plate-shaped body extending rearward rightward is provided on the left part of the upper surface of the transfer shelf (22), and a plate-shaped body extending rearward leftward is provided on the right part of the upper surface of the transfer shelf (22) A first opening (50A) or a second opening provided on the front left side of the rear part of the discharge guide (27) on the upper surface of the transfer shelf (22) in plan view. The long axis of the portion (51A) is provided parallel to the left shift plate (26A), and the long axis of the first opening (50B) or the second opening (51B) provided in the front right portion is set to the right shift plate (26B). This threshing device is characterized by being provided in parallel .

In the invention according to claim 2 , in plan view, the first opening (50C) or the second opening is provided on the upper surface of the transfer shelf (22) on the rear left side of the rear portion of the discharge guide (27). The long axis of (51C) is perpendicular to the left shift plate (26A), and the long axis of the first opening (50D) or the second opening (51D) provided on the rear right side is the right shift plate (26B). The threshing device according to claim 1 , which is provided perpendicular to the .

The invention according to claim 3 is the threshing apparatus according to claim 1 or 2 , wherein the vertical surface part (42) is provided with a third opening (52).

The invention according to claim 4 is the threshing apparatus according to any one of claims 1 to 3 , wherein the rear part of the discharge guide (27) is fixed to the rear part of the lower surface of the transfer shelf (22).

According to the first aspect of the invention, the upper part of the swing sorting device (21) is formed by the transfer shelf (22) made of a plate-like body and the grain sieve (24) made of a plurality of sieves. A plane portion (40) extending in the longitudinal direction of the shelf (22), a slope portion (41) extending rearward and upward from the rear end portion of the plane portion (40), and a rear side of the slope portion (41). It is formed from a vertical surface portion (42) extending downwardly from the end portion, the flat portion (40) having a plurality of first openings (50) and the sloping portion (41) having a plurality of second openings. (51) is provided, and the rear part of the discharge guide (27) made of a plate-like body is fixed to the lower surface of the transfer shelf (22), the discharge guide (27) is extended forward and downward, and the transfer shelf (22 ) is ) is provided with a plate-like body extending rearward and rightward on the left side of the top surface of the transfer rack (22). A first opening (50A) or a second opening provided on the front left side of the rear part of the discharge guide (27) on the upper surface of the transfer shelf (22) in plan view. (51A) is provided parallel to the left shift plate (26A), and the long axis of the first opening (50B) or the second opening (51B) provided on the front right side is parallel to the right shift plate (26B). Since it is provided in the transfer shelf (22), foreign substances such as sand and dust that have leaked down to the transfer shelf (22) are discharged outside the sorting chamber (20), and the frequency of contact between grains and foreign substances is reduced. It can prevent damage to the epidermis.

Contaminants transferred along the left gathering plate (26A) and the right gathering plate (26B) can be efficiently discharged to the outside of the sorting chamber (20). In addition, contaminants that have leaked down to the transfer shelf (22) can be efficiently discharged to the outside of the sorting chamber (20).

According to the invention of claim 2 , in addition to the effect of the invention of claim 1 , in plan view, the discharge guide (27) is provided on the upper surface of the transfer shelf (22) on the rear left side of the rear side of the discharge guide (27). The long axis of the first opening (50C) or the second opening (51C) is provided perpendicular to the left shift plate (26A), and the first opening (50D) or the second opening provided on the rear right side Since the major axis of the part (51D) is provided perpendicular to the right shifter plate (26B), the culms with grains transported along the left shifter plate (26A) and the right shifter plate (26B) are thereby placed in the first direction. 1 opening (50C) or the like can be suppressed and efficiently transferred to the grain sieve (24).

According to the invention of claim 3 , in addition to the effects of the invention of claim 1 or 2 , since the third opening (52) is provided in the vertical surface (42), leakage to the transfer shelf (22) is prevented. Contaminants that have been dropped can be discharged more efficiently to the outside of the sorting chamber (20).

According to the invention of claim 4 , in addition to the effects of the invention of any one of claims 1 to 3 , the rear part of the discharge guide (27) is fixed to the rear part of the lower surface of the transfer shelf (22). Therefore, the contaminants that have leaked down to the transfer shelf (22) can be more efficiently discharged to the outside of the sorting chamber (20).

It is a front view of a combine. It is a left view of a combine. It is a top view of a combine. BRIEF DESCRIPTION OF THE DRAWINGS It is a longitudinal cross-sectional view of the threshing apparatus of 1st Embodiment of the front-back direction. It is a top view of a rocking|swiveling sorting device. (a) is a plan view of a slit in the plane portion of the transfer shelf, and (b) is a left side view of the transfer shelf. FIG. 11 is a plan view of another slit in the plane portion of the transfer shelf; FIG. 11 is a plan view of still another slit in the plane portion of the transfer shelf; (a) is a plan view of a slit in the slope portion of the transfer shelf, and (b) is a left side view of the transfer shelf. FIG. 11 is a plan view of another slit in the slope portion of the transfer shelf; FIG. 11 is a plan view of still another slit in the slope portion of the transfer shelf; (a) is a plan view of a slit in the vertical surface portion of the transfer shelf, (b) is a rear view of the slit in the vertical surface portion, and (c) is a left side view of the transfer shelf. (a) is a plan view of another slit in the vertical surface portion of the transfer shelf, and (b) is a rear view of another slit in the vertical surface portion. (a) is a plan view of still another slit in the vertical surface portion of the transfer shelf, and (b) is a rear view of still another slit in the vertical surface portion. It is the longitudinal cross-sectional view of the front-back direction of the threshing apparatus of 2nd Embodiment.

As shown in FIGS. 1 to 3, the general-purpose combine harvester is provided with a traveling device 2 consisting of a pair of left and right crawlers that travels on the soil surface on the lower side of the body frame 1, and harvests grain stalks in the field on the front side of the body frame 1. A threshing device 4 for threshing and sorting the harvested culms is provided on the rear left side of the pre-harvesting processing device 3, and an operator rides on the rear right side of the pre-harvesting processing device 3. A control section 5 is provided for controlling.

An engine room 6 in which an engine is installed is provided on the lower side of the control unit 5, and a grain tank 7 for storing threshed and sorted grains is provided on the rear side of the control unit 5. A discharge auger 8 is provided for discharging grains to the outside.

The pre-harvesting treatment device 3 includes a conveying device 3A that raises the grain culm in the field and conveys it to the rear side, a cutting blade device 3B that cuts the base of the grain culm conveyed to the rear lower part of the conveying device 3A, It is composed of an auger device 3C that collects the grain culms conveyed to the rear side of the conveying device 3A to the left side, and a feeder house 3D that conveys the collected grain culms to the threshing device 4.

<Threshing device of the first embodiment>
As shown in FIG. 4, the threshing apparatus 4 of the first embodiment comprises a threshing chamber 10 for threshing stalks and a sorting chamber 20 for sorting threshed grains.

On the front and rear walls of the threshing chamber 10, a threshing drum 11 for threshing the stalks conveyed from the feeder house 3D is installed. A receiving net 12 formed in a semicircular arc shape is provided. The upper part of the handling cylinder 11 is covered with an openable and closable handling cylinder cover (not shown), and a dust feed plate for guiding the culms to the rear part of the handling chamber 10 is provided on the inner periphery of the handling cylinder cover. is provided.

At the upper part of the sorting chamber 20, a rocking sorting device 21 for sorting the grains leaking from the handling chamber 10 is provided.

As shown in FIG. 5, above the swing sorting device 21, a transfer shelf 22 formed of a plate-like body is arranged in parallel from the front side at a predetermined interval in the left-right direction and extends in the front-rear direction. A sieve body 23 formed of round steel, a grain sieve 24 formed of a plurality of sieves arranged side by side at predetermined intervals in the front-rear direction and inclined in the vertical direction and extending in the left-right direction, and a predetermined length in the left-right direction. A straw sieve 25 is provided which is formed of a plurality of sieves extending in the front-rear direction and arranged side by side at intervals of . In addition, the inclination angle (opening degree) of the grain sieve 24 can be changed by operating a lever provided on the control section 5 depending on the type of culm to be harvested. As a result, the sorting efficiency can be maintained at a high level regardless of the type of harvested culms.

On the left side of the transfer shelf 22, a left shifting plate 26A that guides the grain stalks and the like conveyed to the transfer shelf 22 to the central portion in the left-right direction is provided and extends toward the rear right side. is provided with a right shifting plate 26B extending rearward and leftward for guiding the culms and the like conveyed to the transfer shelf 22 to the central portion in the left-right direction. In this specification, the left gathering plate 26A and the right gathering plate 26B are collectively referred to as the gathering plate 26. As shown in FIG.

As shown in FIG. 4 , a discharge guide 27 is provided on the lower side of the transfer shelf 22 and extends forward and downward from the intermediate portion of the transfer shelf 22 in the front-rear direction. The length of the ejection guide 27 in the left-right direction is the same as the length of the transfer rack 22 in the left-right direction, and the ejection guide 27 extends from the intermediate portion of the transfer rack 22 in the front-rear direction through the upper side of the winnow 30 to reach the winnow cover 30A. up to the upper front of the As a result, dust such as sand and dust leaked from the slits 50 formed in the transfer shelf 22 can be discharged to the outside of the sorting chamber 20 .

A bucket-shaped grain pan 28 is provided at the bottom of the rocking sorting device 21 to receive grains and the like leaking down from the top.

Below the swing sorting device 21, in order from the front side, a winnow 30 for blowing the sorting air to the swing sorting device 21, a wind splitter 31 for changing the blowing direction of the sorting wind behind the winnow 30, and a swing The first spiral 32 conveys the grains leaking from the sorting device 21 to the grain tank 7, and the swinging sorting device removes the grains with branch stems etc. A number 2 helix 33 is provided for re-conveying to the sorting rack in front of 21 .

(Slit in flat part of transfer shelf)
As shown in FIG. 6, in a left side view, the transfer shelf 22 includes a flat portion 40 extending horizontally in the front-rear direction, a slope portion 41 extending rearward and upward from the rear end portion of the flat portion 40, and a slope It is formed of a vertical surface portion 42 extending downwardly from the rear end of portion 41 .

A flat portion 40 positioned on the front left side of the transfer shelf 22 is formed with a left slit 50A having a long axis extending substantially parallel to the left gathering plate 26A. is formed with a right slit 50B having a long axis extending substantially parallel to the right gathering plate 26B. As a result, dust such as sand and dust transferred along the left-handed plate 26A of the transfer shelf 22 is efficiently leaked from the left slit 50A, and the sand and dust transferred along the right-handed plate 26B of the transfer shelf 22 are discharged. Dust such as dust is efficiently leaked from the right slit 50B to reduce the frequency of contact of grains of soybeans and mung beans with dust such as sand and dust, thereby suppressing damage to soft skins of the grains. be able to. The upper portion of the discharge guide 27 is fixed to a portion of the lower surface of the transfer shelf 22 facing the second vertical surface portion 42 from the front side.

A flat portion 40 positioned on the front left side of the transfer shelf 22 is formed with a left slit 50C having a long axis extending substantially orthogonally to the left shifting plate 26A. is formed with a right slit 50D having a parallel long axis extending substantially orthogonally to the right gathering plate 26B. As a result, the culms transferred along the left shifting plate 26A of the transfer shelf 22 are prevented from leaking from the left slit 50C, and the stalks transferred along the right shifting plate 26B of the transfer shelf 22 are prevented from falling to the right. It is possible to prevent leakage from the slit 50D. In addition, since the sorting wind from the winnow 30 is blown to the upper surface of the transfer rack 22 through the slits 50C and 50D, the culms on the transfer rack 22 can be efficiently transferred to the sieve 23 and grain sieve 24. The left slit 50C and the right slit 50D can be formed in the same shape as the left slit 50A and the right slit 50B, respectively. Thereby, the slits 50A to 50D can be easily formed in the plane portion 40. FIG.

In this specification, the left slit 50A, the right slit 50B, the left slit 50C, and the right slit 50D are collectively referred to as the slit 50 (“first opening” in the claims). Moreover, the slit 50 may be formed together with a slit 51 or a slit 52, which will be described later, or may be formed independently.

FIG. 7 illustrates the left half of transfer shelf 22 . As shown in FIG. 7, a left slit 50A having a long axis extending in the front-rear direction is formed in the plane portion 40 positioned on the front left side of the transfer shelf 22, and positioned on the rear left side of the transfer shelf 22. As shown in FIG. It is also possible to form a left slit 50C having a long axis extending in the front-rear direction in the flat portion 40 . Similarly, a right slit 50B having a long axis extending in the front-rear direction is formed in the flat portion 40 located on the right front side of the transfer shelf 22, and the flat portion 40 located on the right rear side of the transfer shelf 22 is formed. It is also possible to form a right slit 50D having a long axis extending along the front-rear direction. Thereby, the slit 50 can be easily formed in the plane portion 40 . In addition, dust such as sand, dust, etc., which is transferred through the middle portion of the transfer shelf 22 in the left-right direction is efficiently leaked from the left slit 50A and the right slit 50B, and the middle portion in the left-right direction of the transfer shelf 22 is moved back and forth. It is possible to prevent the culms transferred at a predetermined angle from leaking down from the left slit 50C and the right slit 50D.

FIG. 8 illustrates the left half of transfer shelf 22 . As shown in FIG. 8, a left slit 50A having a long axis extending in the left-right direction is formed in the plane portion 40 positioned on the front left side of the transfer shelf 22, and positioned on the rear left side of the transfer shelf 22. It is also possible to form a left slit 50C having a long axis extending in the left-right direction in the flat portion 40. Similarly, a right slit 50B having a long axis extending in the left-right direction is formed in the plane portion 40 located on the front right side of the transfer shelf 22, and the plane portion 40 located on the rear right side of the transfer shelf 22 is formed. It is also possible to form a right slit 50D having a long axis extending in the left-right direction. Thereby, the slit 50 can be easily formed in the plane portion 40 . In addition, dust such as sand, dust, etc., which is transferred through the middle portion of the transfer shelf 22 in the left-right direction is efficiently leaked from the left slit 50A and the right slit 50B, and the middle portion in the left-right direction of the transfer shelf 22 is moved back and forth. It is possible to prevent the culms transferred at a predetermined angle from leaking down from the left slit 50C and the right slit 50D.

(Slit on the slope of the transfer rack)
As shown in FIG. 9, a left slit 51A having a long axis extending substantially parallel to the left shifting plate 26A is formed in the inclined surface portion 41 located on the front left side of the transfer shelf 22, and the front right side of the transfer shelf 22 is formed. A right slit 51B having a long axis extending substantially parallel to the right gathering plate 26B is formed in the slope portion 41 located at the bottom. As a result, the length of the slope portion 41 in the front-rear direction is generally longer than the length of the flat portion 40 in the front-rear direction. Dust such as sand and dust that are transferred along the right shifting plate 26B of the transfer shelf 22 are efficiently leaked from the right slit 51B, so that soybeans and mung beans are efficiently leaked from the left slit 51A. It is possible to reduce the frequency of the grains coming into contact with dust such as sand and dust, and to further suppress damage to the soft outer skin of the grains. The upper portion of the discharge guide 27 is fixed to a portion of the lower surface of the transfer shelf 22 facing the second vertical surface portion 42 from the front side.

A left slit 51C having a long axis extending substantially orthogonally to the left shifting plate 26A is formed on the slant portion 41 positioned on the front left portion of the transfer shelf 22, and the slant portion 41 positioned on the front right portion of the transfer shelf 22 is formed. is formed with a right slit 51D having a parallel long axis extending substantially perpendicularly to the right gathering plate 26B. As a result, the culms transferred along the left shifting plate 26A of the transfer shelf 22 are prevented from leaking from the left slit 51C, and the stalks transferred along the right shifting plate 26B of the transfer shelf 22 are prevented from falling to the right. It is possible to prevent leakage from the slit 51D. In addition, since the sorting wind from the winnow 30 is blown to the upper surface of the transfer rack 22 through the slits 51C and 51D, the culms on the transfer rack 22 can be efficiently transferred to the sieve 23 and grain sieve 24. The left slit 51C and the right slit 51D can also be formed in the same shape as the left slit 51A and the right slit 51B, respectively. Thereby, the slits 51A to 51D can be easily formed in the slope portion 41. As shown in FIG.

In this specification, the left slit 51A, the right slit 51B, the left slit 51C, and the right slit 51D are collectively referred to as the slit 51 (“second opening” in the claims). Also, the slit 51 may be formed together with the slit 50 or a slit 52 described later, or may be formed independently.

FIG. 10 illustrates the left half of transfer shelf 22 . As shown in FIG. 10, a left slit 51A having a long axis extending in the front-rear direction is formed in the sloped portion 41 positioned on the front left side of the transfer shelf 22, and positioned on the rear left side of the transfer shelf 22. As shown in FIG. A left slit 51C having a long axis extending in the front-rear direction can also be formed in the inclined surface portion 41. Similarly, a right slit 51B having a long axis extending in the front-rear direction is formed in the sloped portion 41 located on the front right side of the transfer shelf 22, and the sloped portion 41 located on the rear right side of the transfer shelf 22 is formed. It is also possible to form a right slit 51D having a long axis extending along the front-rear direction. Thereby, the slit 51 can be easily formed in the slope portion 41 . In addition, dust such as sand, dust, etc., which is transferred through the intermediate portion of the transfer shelf 22 in the lateral direction is efficiently leaked from the left slit 51A and the right slit 51B, and the intermediate portion of the transfer shelf 22 in the lateral direction is moved forward and backward. It is possible to prevent the culms transferred at a predetermined angle from leaking down from the left slit 51C and the right slit 51D.

FIG. 11 illustrates the left half of transfer shelf 22 . As shown in FIG. 11, a left slit 51A having a long axis extending in the left-right direction is formed in the sloped portion 41 positioned on the front left side of the transfer shelf 22, and positioned on the rear left side of the transfer shelf 22. As shown in FIG. It is also possible to form a left slit 51C having a long axis extending in the left-right direction in the inclined surface portion 41. Similarly, a right slit 51B having a long axis extending in the left-right direction is formed in the slope portion 41 located on the front right side of the transfer shelf 22, and the slope portion 41 located on the rear right side of the transfer shelf 22 is formed. It is also possible to form a right slit 51D having a long axis extending in the left-right direction. Thereby, the slit 51 can be easily formed in the slope portion 41 . In addition, dust such as sand, dust, etc., which is transferred through the intermediate portion of the transfer shelf 22 in the lateral direction is efficiently leaked from the left slit 51A and the right slit 51B, and the intermediate portion of the transfer shelf 22 in the lateral direction is moved forward and backward. It is possible to prevent the culms transferred at a predetermined angle from leaking down from the left slit 51C and the right slit 51D.

(Slit in the vertical surface of the transfer shelf)
FIG. 12 illustrates the left half of transfer shelf 22 . As shown in FIG. 12, the vertical surface portion 42 of the transfer shelf 22 is formed with a slit 52 (a "third opening" in the claims) having a long axis extending at a predetermined angle with respect to the vertical direction. there is As a result, dust such as sand and dust transferred to the flat portion 40 of the transfer shelf 22 is efficiently leaked from the slits 52 to prevent it from staying at the corners of the flat portion 40 and the vertical surface portion 42, so that the soybeans can be transported. It is possible to reduce the frequency of contact of mung bean kernels with dust such as sand and dust, thereby suppressing damage to the soft outer skin of the kernels. In addition, the culms transferred to the flat portion 40 are prevented from leaking through the slits 52, and transferred to the sieve 23 and the grain sieve 24 at the rear to maintain high grain recovery efficiency. The slits 52 may be formed together with the slits 50 and 51, or may be formed independently.

FIG. 13 illustrates the left half of transfer shelf 22 . As shown in FIG. 13, the vertical surface portion 42 of the transfer shelf 22 is formed with a slit 52 having a longitudinal axis extending along the vertical direction. Thereby, the slit 52 can be easily formed in the vertical surface portion 42 .

FIG. 14 illustrates the left half of transfer shelf 22 . As shown in FIG. 14, the vertical surface portion 42 of the transfer shelf 22 is formed with a slit 52 having a long axis extending in the left-right direction. Thereby, the slit 52 can be easily formed in the vertical surface portion 42 .

<Threshing device of the second embodiment>
FIG. 15 shows the threshing device 4 of the second embodiment. The same reference numerals are assigned to the same members, and the description thereof is omitted.

A discharge guide 27 is provided on the lower side of the transfer shelf 22 and extends forward and downward from the rear end portion of the transfer shelf 22 in the front-rear direction. The length of the ejection guide 27 in the left-right direction is the same as the length of the transfer rack 22 in the left-right direction, and the ejection guide 27 extends from the intermediate portion of the transfer rack 22 in the front-rear direction through the upper side of the winnow 30 to reach the winnow cover 30A. up to the upper front of the As a result, all the dust such as sand and dust leaked from the slits 50 formed in the transfer shelf 22 can be discharged to the outside of the sorting chamber 20 . As described above, the flat surface portion 40 of the transfer shelf 22 is formed with the slit 50 , the inclined surface portion 41 is formed with the slit 51 , and the vertical surface portion 42 is formed with the slit 52 .

10 Handling chamber 20 Sorting chamber 21 Swing sorting device 22 Transfer shelf 24 Glen sieve 26A Left gathering plate 26B Right gathering plate 27 Discharge guide 40 Plane portion 41 Slope portion 42 Vertical surface portion 50 Slit (first opening)
51 slit (second opening)
52 slit (third opening)

Claims (7)

A threshing apparatus comprising a sorting chamber (20) for sorting and processing processed materials leaking from the threshing chamber (10) below the threshing chamber (10) for threshing the culms,
A rocking sorting device (21) is provided in the upper part of the sorting chamber (20),
The upper part of the oscillating sorting device (21) is formed by a transfer shelf (22) made of a plate-like body and a grain sieve (24) made of a plurality of sieves,
A plurality of first openings (50) or second openings (51) are provided in the transfer shelf (22),
A threshing apparatus characterized in that the rear part of a plate-like discharge guide (27) is fixed to the lower surface of the transfer rack (22), and the discharge guide (27) extends forward and downward. A left shifting plate (26A) made of a plate-like body extending toward the rear right side is provided on the left part of the upper surface of the transfer shelf (22),
A right shifting plate (26B) made of a plate-like body extending rearward and leftward is provided on the right part of the upper surface of the transfer shelf (22),
In plan view, the long axis of the first opening (50A) or the second opening (51A) provided on the front left side of the rear part of the discharge guide (27) on the upper surface of the transfer shelf (22) is aligned with the left alignment plate. (26A), and the major axis of the first opening (50B) or the second opening (51B) provided on the front right side is provided parallel to the right shifting plate (26B). Device. In plan view, the long axis of the first opening (50C) or the second opening (51C) provided on the rear left side of the rear part of the discharge guide (27) on the upper surface of the transfer shelf (22) is shifted to the left. A claim in which the plate (26A) is provided perpendicularly, and the long axis of the first opening (50D) or the second opening (51D) provided in the rear right portion is provided perpendicularly to the right shifting plate (26B). 2. The threshing device according to 2. In a left side view, a plane portion (40) extending in the front-rear direction of the transfer shelf (22), and a slope portion (41) extending rearward and upward from the rear end portion of the plane portion (40). , a vertical surface portion (42) extending downward from the rear end of the inclined surface portion (41);
The threshing device according to any one of claims 1 to 3, wherein the first opening (50) is provided in the plane portion (40). In a left side view, a plane portion (40) extending in the front-rear direction of the transfer shelf (22), and a slope portion (41) extending rearward and upward from the rear end portion of the plane portion (40). , a vertical surface portion (42) extending downward from the rear end of the inclined surface portion (41);
The threshing device according to any one of claims 1 to 3, wherein the second opening (51) is provided on the slope (41). The threshing device according to claim 4 or 5, wherein the vertical surface (42) is provided with a third opening (52). The threshing apparatus according to any one of claims 1 to 6, wherein the rear part of the discharge guide (27) is fixed to the rear part of the lower surface of the transfer shelf (22).

Images