JP6870665B2 - combine - Google Patents

Description

The present invention relates to a combine in which a threshing device is provided with a fried grain cylinder for reducing the second product.

In the conventional combine, a frying cylinder is provided to reduce the second product such as stabbed grains that have been threshed and sorted by the threshing device to the upstream part of the sorting shelf of the threshing device, and impurities are discharged to the outer periphery of the threshing cylinder. A technique for providing a filtration member has been known. (Patent Document 1)

Japanese Unexamined Patent Publication No. 2005-13107

However, in the technique of Patent Document 1, in the case of a variety and working conditions in which straw dust and the like are likely to be generated, the straw dust and the like cannot be sufficiently separated in the transport process by the transport cylinder, and there is room for further improvement. ..

Therefore, an object of the present invention is to provide a combine capable of efficiently separating and filtering foreign substances such as straw debris in the second product in a frying cylinder that reduces the second product to a threshing device. It is in.

The present invention that solves the above problems is as follows.

That is, in the invention according to claim 1, a threshing device (4) for threshing and sorting the winnowing is provided on the upper side of the machine frame (1), and the threshing and sorting process is performed on the right side of the threshing device (4). In the combine provided with the grain tank (7) for storing the grains, the first threshing cylinder (36) for transporting the grains from the threshing device (4) to the grain tank (7) is provided, and the first threshing device is provided. The second fried grain that connects the rear part and the front part of the right wall (4B) of the threshing device (4) to the left side of the cylinder (36) and reduces the second product from the lower part to the upper part of the threshing device (4). The cylinder (41) is provided in a downwardly inclined posture, and the second threshing cylinder (41) is provided with a transport spiral (46) and a cylinder (45) covering the transport spiral (46). The dust exhaust port (42) formed on the lower surface side of the threshing cylinder (41) is provided with a dust exhaust filtration member (42A) having a plurality of filtration holes, and the inner peripheral surface of the dust exhaust filtration member (42A) is set as described above. It is a combine arranged closer to the outer peripheral edge of the transport spiral (46) than the inner peripheral surface of the cylinder (45).

In the invention according to claim 2, the intermediate portion (42D) of the transport spiral (46) in the transport direction of the dust filter member (42A) is more transport spiral than the upstream portion (42C) and the downstream portion (42E). The combine according to claim 1, which is formed in a shape recessed toward the inside of the tubular body (45) so as to approach (46).

In the invention according to claim 3, the second fried grain cylinder (41) is connected to a lower metal (43) connected to the rear part of the right wall (4B) and to the front part of the right wall (4B). The upper metal (44), the tubular body (45) connecting the lower metal (43) and the upper metal (44), and the transport spiral (46) built in the tubular body (45) are formed. The upper portion of the lower metal (43) and the lower connecting portion (47) of the tubular body (45) are made movable in the vertical direction with respect to the rotation axis (46A) of the transport spiral (46), and the upper metal (46). The lower part of the 44) and the upper connecting part (48) of the tubular body (45) can be moved in the vertical direction with respect to the rotating shaft (46A) of the transport spiral (46), and the rotating shaft (46A) is made of the lower metal. The combine according to claim 1 or 2, characterized in that the upper portion of (43) and the lower portion of the upper metal (44) are rotatable.

The invention according to claim 4 describes the longitudinal direction of the elongated hole (47A) formed in the lower connecting portion (47) and the longitudinal direction of the elongated hole (48A) formed in the upper connecting portion (48). The combine according to claim 3, which is formed along a direction orthogonal to the rotation axis (46A).

According to the invention of claim 1, since the inner peripheral surface of the dust filtration member (42A) is arranged closer to the outer peripheral edge of the transport spiral (46) than the inner peripheral surface of the tubular body (45). , It is possible to enhance the separation / stirring action of the second product by the dust filtration member (42A) and efficiently discharge straw dust and the like to the outside of the second fried grain cylinder (41).

According to the invention of claim 2, in addition to the effect of the invention of claim 1, the dust filter member (42A) has an intermediate portion (42D) in the transport direction of the transport spiral (46), which is an upstream portion. Since it is formed in a concave shape toward the inside of the cylinder (45) so as to be closer to the transport spiral (46) than the (42C) and the downstream portion (42E), the straw is suppressed while suppressing the damage of grains. It is possible to enhance the discharge action of waste and the like.

According to the invention of claim 3, in addition to the effect of the invention of claim 1 or 2, the lower metal (43) connecting the second fried grain cylinder (41) to the rear part of the right wall (4B). ), The upper metal (44) connected to the front part of the right wall (4B), the cylinder (45) connecting the lower metal (43) and the upper metal (44), and the inside of the cylinder (45). It is formed by a transport spiral (46) provided on the peripheral portion, and the upper portion of the lower metal (43) and the lower connecting portion (47) of the tubular body (45) are orthogonal to the rotation axis (46A) of the transport spiral (46). The lower part of the upper metal (44) and the upper connecting part (48) of the tubular body (45) can be moved in the vertical direction orthogonal to the rotation axis (46A) of the transport spiral (46). Since the rotation shaft (46A) is rotatable between the upper part of the lower metal (43) and the lower part of the upper metal (44), the distance between the cylinder (45) and the transport spiral (46) can be easily adjusted according to the harvested material. It can be adjusted and the second product can be efficiently returned to the grain removal device (4).

According to the invention of claim 4, in addition to the effect of the invention of claim 3, the long shaft of the elongated hole (47A) formed in the lower connecting portion (47) and the upper connecting portion (48) are formed. Since the long axis of the long hole (48A) is formed along the direction orthogonal to the rotation axis (46A), the distance between the tubular body (45) and the transport spiral (46) can be adjusted more easily, and the second product. Can be efficiently reduced by the threshing device (4).

It is a top view of the combine. It is a left side view of the combine. It is a front view of a purification device. It is a front perspective view of a purification device. It is a rear perspective view of a purification device. It is a front perspective view of the supply device which supplies urea. It is a right side view of the first fried grain cylinder and the second fried grain cylinder. It is explanatory drawing of the gap between the spiral part and the cylinder part of the 2nd fried grain cylinder, and the harvested matter is rice and wheat, (b) is soybean, and (C) is the case of Kintoki. 8A arrow view, S2-S2 cross section, S1-S1 cross section of FIG. It is explanatory drawing of the discharge port of the 1st winnowing cylinder. It is explanatory drawing of the connection pipe connected to the purification device and a tail pipe. It is another arrangement form of the tail pipe of FIG. It is the side view of the main part which shows the periphery of the dust filter member, and the view in the axial direction of a transport spiral. It is explanatory drawing which shows the mode of the dust exhaust filtration member.

As shown in FIGS. 1 and 2, the general-purpose combine is provided with a traveling device 2 composed of a pair of left and right crawlers traveling on the soil surface under the aircraft frame 1, and harvests culms in the field on the front side of the aircraft frame 1. A pre-cutting processing device 3 is provided, a threshing device 4 for threshing and sorting harvested culms is provided on the rear left side of the pre-cutting processing device 3, and an operator is on the rear right side of the pre-cutting processing device 3. The control unit 5 is provided.

An engine room 6 for mounting an engine 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, and the rear side of the grain tank 7 is provided. Is provided with a discharge cylinder 8 for discharging grains to the outside.

The pre-cutting treatment device 3 includes a transport device 3A for transporting the grain culms in the field to the rear side while standing up, a cutting blade device 3B for cutting the stock of the grain culms transported to the lower rear portion of the transport device 3A, and transport. It is composed of an auger device 3C that collects the culms transported to the rear side of the device 3A to the left side, and a feeder house 3D that collects the collected culms to the grain removal device 4.

As shown in FIGS. 3 to 5, a purification device 10 for purifying the exhaust gas burned by the engine is connected to the engine.

The purification device 10 includes an exhaust purification device (DPF) 12 that purifies impurities in the exhaust gas and a urea purification device (SCR) 14 that purifies nitrogen oxides in the exhaust gas exhausted from the exhaust gas purification device 12. .. The exhaust gas purification device 12 is equipped with an oxidation catalyst (DOC) on the upstream side and a particulate filter (DPF) on the downstream side.

The exhaust port of the engine and the inflow port formed in the front part of the exhaust purification device 12 are connected by a flexible connecting pipe 11, and the outflow port formed in the rear part of the exhaust purification device 12 and the front of the urea purification device 14 are connected. The inflow port formed in the portion is connected by a flexible connecting pipe 13, and the flexible connecting pipe 15 is connected to the outlet formed in the rear portion of the urea purification device 14.

An injection device 17 that injects urea water into the urea purification device 14 via the connection pipe 13 is connected to the rear part of the connection pipe 13, and urea water is pumped to the injection device 17 via a flexible connection pipe. A supply device 18 is connected to the pump, and a urea water tank (not shown) for storing urea water is connected to the supply device 18 via a flexible connecting pipe.

The purification device 10 is mounted on the purification device frame 20, and the front portion of the purification device frame 20 is fixed to the driver's seat frame 50 extending in the left-right direction supporting the driver's seat of the control unit 5, and the purification device frame 20 is fixed. The left portion is fixed to a threshing frame 63 extending in the front-rear direction provided on the upper part of the right wall 4B of the threshing device 4.

The exhaust gas purification device 12 is provided on the left side of the purification device frame 20 on the threshing device 4 side, and the urea purification device 14 is provided on the right side of the purification device frame 20 on the Glen tank 7 side. Further, the upper portions of the exhaust gas purification device 12 and the urea purification device 14 are provided at substantially the same positions in the vertical direction as the handle cylinder cover 60 provided above the handle cylinder of the threshing device 4.

The front portion of the left wall 7A of the grain tank 7 facing the purification device 10 is formed with notches S having openings on the front side and the left side. As a result, the purification device 10 can be provided between the threshing device 4 and the grain tank 7.

The parts of the left wall 7A of the grain tank 7 located in front of the first fried grain cylinder 36 are the upper vertical wall 31 and the upper inclined wall extending downward and to the right from the lower end of the upper vertical wall 31 in the front view. 32, a vertical wall 33 extending downward from the lower end of the upper inclined wall 32, a lower inclined wall 34 extending downward to the left from the lower end of the vertical wall 33, and a lower portion of the lower inclined wall 34. It is formed by a lower vertical wall 35 extending to the side. Further, the notch portion S refers to a space partitioned by an upper inclined wall 32, a vertical wall 33, and a lower inclined wall 34.

The upper inclined wall 32 extends downward to the right at an inclination angle of 45 degrees with respect to the horizontal plane, the vertical wall 33 is formed above the transport spiral of the Glen tank 7, and the lower inclined wall 34 is inclined with respect to the horizontal plane. It extends downward to the left at an angle of 30 degrees. As a result, the grains transported to the grain tank 7 by the first fried grain cylinder 36 can be efficiently dropped onto the transport spiral.

The left portion of the driver's seat frame 50 is connected to the inverted U-shaped left frame 52 provided in the front intermediate portion of the airframe frame 1 via a connecting member 51 extending in the vertical direction, and the driver's seat frame 50 is connected to the left portion of the driver's seat frame 50. The right portion is connected to the inverted U-shaped right frame 54 provided on the front right portion of the airframe frame 1 via a connecting member 53 extending in the vertical direction.

The left portion of the handling cylinder cover 60 of the threshing device 4 is rotatably supported by a support shaft 61 extending in the front-rear direction provided above the left wall 4A of the threshing device 4. As a result, during maintenance of the handling cylinder or the like, a large space can be formed above the handling cylinder by rotating the left portion of the handling cylinder cover 60 around the support shaft 61.

The extending portion 62 extending to the right side provided at the lower right side of the handling body cover 60 is detachably fixed to the threshing frame 63 extending in the front-rear direction provided above the right wall 4B of the threshing device 4. ing.

The rear portion of the threshing frame 63 is connected to the machine frame 1 via a connecting member 55 extending in the vertical direction. As a result, deformation of the threshing frame 63 can be prevented, and the purification device frame 20 can be reliably supported by the cockpit frame 50 and the threshing frame 63.

The connecting pipe 15 extends from the outlet of the urea purification device 14 to the vicinity of the upper inclined wall 32 of the notch S of the grain tank 7, and then bends approximately 90 degrees to the left and first lifts to the left. It extends to the left side through between the transmission portion 39 formed by extending downward to the discharge port 37 of the grain cylinder 36 and the first fried grain cylinder 36, and then bends to the rear side by approximately 90 degrees. Then, it is extended rearward while being close to the left part of the first fried grain cylinder 36. As a result, the handling body cover 60 can be easily rotated around the support shaft 61. Further, the connecting pipe 15 is detachably fixed to the first fried grain cylinder 36 via a stay (not shown) provided at the front portion of the first fried grain cylinder 36.

As shown in FIGS. 6 and 7, a first fried grain cylinder 36 connected to the lower part of the right wall 4B of the threshing device 4 and the upper part of the left wall 7A of the grain tank 7 is provided behind the purification device 10. There is. Further, between the right wall 4B of the threshing device 4 and the first fried grain 36, a second fried grain 41 for returning the second product such as stabbed grains to the upstream portion of the sorting shelf of the threshing device 4 is provided. Has been done.

In the present embodiment, the lower metal 43 of the second fried grain cylinder 41 is used as a reduction outlet formed in the lower part of the right wall 4B of the threshing device 4 located behind the first fried grain cylinder 36, and is a second. The upper metal 44 of the frying cylinder 41 is connected to a reduction outlet formed in the front portion of the right wall 4B of the threshing device 4 located below the purification device 10.

The supply device 18 for pumping urea water to the injection device 17 is fixed to the machine frame 1 via the support member 19. The support member 19 is formed of a front frame 19A formed in a substantially U shape in a front view, a rear frame 19B, and a connecting member 19C connecting the left portion of the front frame 19A and the left portion of the rear frame 19B. There is.

The supply device 18 is detachably attached to the right surface of the connecting member 19C, and the lower portions of the front frame 19A and the rear frame 19B are fixed to the airframe frame 1, and the front frame 19A, the rear frame 19B, and the connecting member 19C are It is not directly connected to the purification device frame 20 on which the purification device 10 is placed, the connecting member 55 that supports the purification device frame 20, or the like. As a result, it is possible to suppress the vibration of the purification device 10 from being transmitted to the supply device 18.

In front view, the supply device 18 is provided between the first winnowing cylinder 36 and the second winnowing cylinder 41. As a result, the traveling wind generated when the vehicle body travels can be efficiently blown rearward between the threshing device 4 and the grain tank 7.

In the side view, the supply device 18 is provided in front of the dust outlet 42 of the second grain raising cylinder 41 in the front-rear direction. As a result, it is possible to prevent dust such as straw dust falling from the dust discharge port 42 from accumulating on the supply device 18.

A wall insert 66 that blows sorting air to the sorting shelf is provided in the lower part of the front side of the threshing device 4. In the rotation axis view of the wall insert 66, the supply device 18 is arranged on the rear upper side of the intake port 67 of the wall insert 66. As a result, the front portion of the intake port 67 is opened, and a large amount of air can be sucked from the front portion of the intake port 67 toward the wall insert 66.

As shown in FIGS. 8 and 9, the second fried grain cylinder 41 is provided inside the lower metal 43, the upper metal 44, the cylinder 45 connecting the lower metal 43 and the upper metal 44, and the cylinder 45. It is formed from a transport spiral 46 for frying the second product.

The lower portion of the rotating shaft 46A of the transport spiral 46 is rotatably fixed to the lower metal 43, and the upper portion of the rotating shaft 46A of the transport spiral 46 is rotatably fixed to the upper metal 44.

The lower portion of the tubular body 45 is formed of an upper portion and a lower portion located below the upper portion. A rectangular lower connecting portion 47 is provided on the upper outer peripheral portion orthogonal to the rotating shaft 46A in the upper portion, and a rectangular lower connecting portion 47 is provided on the lower outer peripheral portion orthogonal to the rotating shaft 46A in the lower portion. Is provided. Further, a rectangular upper connecting portion 48 is provided on the outer peripheral portion of the upper portion of the tubular body 45 orthogonal to the rotation axis 46A.

An elongated hole 47A having a long axis in the vertical direction orthogonal to the rotation axis 46A is formed on both left and right sides of the upper portion of the lower connecting portion 47 provided in the upper portion of the lower part of the tubular body 45, and the tubular body 45 is formed. On both sides of the lower portion of the lower connecting portion 47 provided in the lower portion of the lower portion in the left-right direction, elongated holes 47A having a major axis in the vertical direction orthogonal to the rotation axis 46A are formed. Further, elongated holes 48A having a major axis in the vertical direction orthogonal to the rotation axis 46A are formed on both sides of the upper portion and the lower portion of the upper connecting portion 48 in the left-right direction.

The lower connecting portion 47 is fixed so as to be movable in the vertical direction by a fastening means 49 such as a bolt inserted into the elongated hole 47A in the vicinity of the carry-out port of the lower metal 43. Further, the upper connecting portion 48 is fixed so as to be movable in the vertical direction by a fastening means 49 such as a bolt inserted into the elongated hole 48A in the vicinity of the carry-in entrance of the upper metal 44. The vertical direction means a direction orthogonal to the rotation axis 46A shown in FIG. As a result, the lower connecting portion 47 and the upper connecting portion 48 are moved in the vertical direction according to the harvested product to be harvested, and the distance between the lower inner peripheral portion of the tubular body 45 and the lower outer peripheral portion of the transport spiral 46 is easily established. Can be adjusted to.

As shown in FIGS. 8 and 9 (a), in the case of rice and wheat having a small particle size, the lower connecting portion 47 and the upper connecting portion 48 are moved in the downward direction orthogonal to the rotation axis 46A to form a cylinder. The distance T between the lower inner peripheral portion of the 45 and the lower outer peripheral portion of the transport spiral 46 is made narrower than a predetermined distance. This prevents the second rice and wheat from falling from between the lower inner circumference of the cylinder 45 and the lower outer circumference of the transport spiral 46 toward the lower metal 43 during threshing, and rice. , The second grain of wheat can be efficiently returned to the upstream part of the sorting shelf of the threshing device 4.

As shown in FIGS. 8 and 9 (c), in the case of gold having a large particle size, the lower connecting portion 47 and the upper connecting portion 48 are moved upward to the inner peripheral lower portion of the tubular body 45 and the transport spiral 46. The interval T between the lower part of the outer circumference of the above is wider than the predetermined interval. As a result, it is possible to prevent the surface of the second product of gold time from being scratched during frying, and to efficiently return the second product of gold time to the upstream portion of the sorting shelf of the threshing device 4.

As shown in FIGS. 8 and 9 (b), in the case of soybean having a particle size larger than that of rice and wheat and smaller than that of gold, the lower connecting portion 47 and the upper connecting portion 48 are vertically aligned with the rotation axis 46A. Moving to an intermediate position in the direction, the interval T between the lower inner peripheral portion of the tubular body 45 and the lower outer peripheral portion of the transport spiral 46 is set to a predetermined interval. As a result, the second soybean product can be efficiently reduced to the upstream portion of the sorting shelf of the threshing device 4 at the time of frying.

It is preferable to mark rice, wheat, etc. in the vicinity of the elongated hole 47A of the lower connecting portion 47 and the elongated hole 48A of the upper connecting portion 48. As a result, the lower connecting portion 47 and the upper connecting portion 48 can be easily moved and fixed according to the marks of rice, wheat and the like.

Further, a dust filtration member 42A covering the dust exhaust port 42 is attached to the dust exhaust port 42 of the second grain raising cylinder 41 described above. The dust filter member 42A is a member having a plurality of filtration holes, and is formed of, for example, a punching plate or a net.

As shown in FIG. 13, the inner peripheral surface 42B of the dust filtration member 42A is located inside the inner peripheral surface of the tubular body 45 (the side closer to the rotating shaft 46A than the inner peripheral surface of the tubular body 45). For example, it is located about 2 mm to 5 mm inside the inner peripheral surface of the tubular body 45. As a result, impurities such as straw dust contained in the object to be treated can be efficiently discharged to the outside of the supply device 18. In addition, the supply device 18 can be compactly configured while having the dust filtration member 42A, and problems such as interference with surrounding members and reduction of ventilation space can be suppressed.

Further, the dust exhaust filtration member 42A is inside the cylinder 45 so that the upstream portion 42C and the downstream portion 42E in the transport direction are low and become higher toward the central portion 42D (also referred to as “intermediate portion”) in the transport direction. It is formed in a shape that bulges toward. By forming the upstream portion 42C and the downstream portion 42E of the dust exhaust filtration member 42A low in this way, it is possible to suppress damage to grains and transport stagnation at the boundary portion between the cylinder 45 and the dust exhaust filtration member 42A. it can. Further, since the central portion 42D is formed high, it is possible to effectively remove impurities such as straw debris contained in the transported material, suppress the processing load of the threshing apparatus 4, and improve the processing efficiency. Can be made to.

Further, the filtration holes provided in the dust exhaust filtration member 42A are formed in a shape long in the tangential direction in the spiral outer peripheral portion of the transport spiral 46. That is, the filtration hole is formed to have a larger dimension in the direction parallel to the tangential direction in the spiral outer peripheral portion than the dimension in the direction orthogonal to the tangential direction in the spiral outer peripheral portion of the transport spiral 46.

As a result, the long straw debris contained in the object to be processed supplied to the second fried grain cylinder 41 can be efficiently discharged to the outside of the machine. Since the elongated straw waste is transported while being pushed up by the outer peripheral portion of the transport spiral 46 in the transport process of the transport spiral 46, it is often in a posture along the tangential direction of the transport spiral 46. It is possible to prevent the leakage of grains while efficiently discharging straw waste.

The method of setting the shape of the filtration hole in this way is arbitrary, but for example, a net composed of a horizontal member 42F which is a wire rod along the tangential direction in the spiral outer peripheral portion and a vertical member 42G which is a wire rod in the direction orthogonal to the horizontal member 42F is used. The wire pitch of the vertical member 42G can be increased (see A in FIG. 14), or the plate material can be punched into an elongated hole shape (see B in FIG. 14).

Note that X and Y in FIG. 14 indicate the circumferential direction and the axial direction of the rotating shaft 46A, respectively, and U and V indicate the tangential direction at the outer peripheral portion of the spiral of the transport spiral 46 and the direction orthogonal to the tangential direction, respectively.

As shown in FIG. 10, the discharge port 37 of the first fried grain cylinder 36 is provided with a rotating plate 38A supported by a rotating shaft 38 extending in the vertical direction, and the upper surface of the rotating plate 38A is provided with a rotating plate 38A. A substantially trapezoidal discharge member 38B is erected. As a result, the discharge member 38B can give momentum to the grains and discharge the grains to the distal portion away from the discharge port 37 in the grain tank 7.

The upper part of the discharge member 38B extends to a position lower than the upper part of the discharge port 37. As a result, the grains passing above the upper part of the discharge member 38B are discharged to the proximal portion of the discharge port 37 in the grain tank 7, and the grains can be uniformly discharged to the grain tank 7. .. A transmission unit 39 for transmitting the output rotation of the engine is provided on the rotation shaft 38 on the lower side of the discharge port 37.

As shown in FIG. 11, a tail pipe 16 fixed to the left side of the first winnowing cylinder 36 is connected to the outlet of the connecting pipe 15. The tail pipe 16 can also be fixed to the right side of the second fried grain cylinder 41.

The inner diameter of the inlet of the connecting pipe 15 is formed to be larger than the outer diameter of the outlet of the urea purification device 14. As a result, the air around the outlet of the urea purification device 14 can be sucked into the connecting pipe 15 to lower the temperature of the exhaust gas discharged from the urea purification device 14 to the connecting pipe 15. Further, the inner diameter of the inflow port of the tail pipe 16 is formed to be larger than the outer diameter of the outflow port of the connecting pipe 15. As a result, the air around the outlet of the connecting pipe 15 can be sucked into the tail pipe 16 to lower the temperature of the exhaust gas discharged from the connecting pipe 15 to the tail pipe 16.

The inlet of the connecting pipe 15 is inserted into the outlet of the urea purification device 14 with a predetermined gap, and the outlet of the connecting pipe 15 is inserted into the inlet of the tail pipe 16 with a predetermined gap. It is fitted. As a result, with the urea purification device 14 and the tail pipe 16 fixed, the connection pipe 15 can be moved in the front-rear direction and attached to and detached from the urea purification device 14 and the tail pipe 16 to easily replace the connection pipe 15. ..

As shown in FIG. 12, the tail pipe 16 can also be provided with a downward slope. As a result, it is possible to prevent rainwater that has entered the tail pipe 16 from entering the urea purification device 14 via the connecting pipe 15.

1 Aircraft frame 4 Threshing device 4B Right wall 7 Glen tank 36 1st fried grain cylinder 41 2nd fried grain cylinder 42 Dust exhaust port 42A Dust exhaust filtration member 42C Upstream part 42D Central part (middle part)
42E Downstream 43 Lower metal 44 Upper metal 45 Cylinder 46 Transport spiral 46A Rotating shaft 47 Lower connecting 47A Long hole 48 Upper connecting 48A Long hole

Claims (4)

A threshing device (4) for threshing and sorting the grain culms is provided on the upper side of the machine frame (1), and a grain tank (7) for storing the threshed and sorted grains is stored on the right side of the threshing device (4). In the combine that provided
A first frying cylinder (36) for transporting grains from the threshing device (4) to the grain tank (7) is provided.
The second product is reduced from the lower part to the upper part of the threshing device (4) by connecting the rear part and the front part of the right wall (4B) of the threshing device (4) to the left side of the first threshing device (36). The second threshing cylinder (41) to be used is provided in a downwardly inclined posture.
The second fried grain cylinder (41) is provided with a transport spiral (46) and a cylinder (45) covering the transport spiral (46).
A dust filtration member (42A) having a plurality of filtration holes is provided in the dust exhaust port (42) formed on the lower surface side of the second grain raising cylinder (41).
A combine in which the inner peripheral surface of the dust filtration member (42A) is arranged closer to the outer peripheral edge of the transport spiral (46) than the inner peripheral surface of the tubular body (45). The dust filter member (42A) is cylinderd so that the intermediate portion (42D) of the transport spiral (46) in the transport direction is closer to the transport spiral (46) than the upstream portion (42C) and downstream portion (42E). The combine according to claim 1, wherein the combine is formed in a shape recessed toward the inside of the body (45). The second fried grain cylinder (41) is connected to the lower metal (43) connected to the rear part of the right wall (4B) and the upper metal (44) connected to the front part of the right wall (4B). It is formed by the tubular body (45) connecting the lower metal (43) and the upper metal (44) and the transport spiral (46) incorporated in the tubular body (45).
The upper portion of the lower metal (43) and the lower connecting portion (47) of the tubular body (45) can be moved in the vertical direction with respect to the rotation axis (46A) of the transport spiral (46).
The lower portion of the upper metal (44) and the upper connecting portion (48) of the tubular body (45) can be moved in the vertical direction with respect to the rotation axis (46A) of the transport spiral (46).
The combine according to claim 1 or 2, wherein the rotating shaft (46A) is rotatable on the upper portion of the lower metal (43) and the lower portion of the upper metal (44). The longitudinal direction of the elongated hole (47A) formed in the lower connecting portion (47) and the longitudinal direction of the elongated hole (48A) formed in the upper connecting portion (48) are orthogonal to the rotation axis (46A). The combine according to claim 3, which is formed along the direction.

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