JP6312582B2 - Combine - Google Patents

Description

  The present invention relates to a combine, and more particularly, to a normal combine that scrapes a harvested stalk crop with a scraping auger and takes it into a threshing section through a feeder house.

  Conventionally, there exists what was disclosed by patent document 1 as one form of a combine. That is, Patent Document 1 discloses a normal type in which a harvested stem-and-cropping crop (rice plant such as rice and wheat) is scraped into a feeder house with a scraping auger and taken into a threshing section through the feeder house. A combine is disclosed. The take-up auger is configured such that a cylindrical auger body having an axis line in the left-right direction is rotatably mounted in the grain header. On the outer peripheral surface of the auger body, a left spiral conveyance piece and a right spiral conveyance piece are formed so as to protrude, and a cylindrical shape in which the harvested stalk crops are gathered between the inner ends of both spiral conveyance pieces. Forms a space for harvesting stems. Moreover, the cutting stalk gathering space is formed so as to coincide with the communication port formed in the rear wall portion of the grain header so as to communicate with the feeder house in the front-rear direction. On the outer peripheral surface portion of the auger main body where the cutting stalk gathering space is formed, there are provided a squeezing finger that can be moved in and out and a rake plate that undulates in synchronism with the rising and falling of the squeezing finger. Then, the erection body prevents the stalk crop from being wound around the auger body.

Japanese Patent Laid-Open No. 10-14

  However, in the above-described combine, even if the standing auger plate prevents the stalk crops from being wrapped around the auger body, the scraper plate is not scratched toward the communication port side with respect to the stalks and crops. It acts in the opposite direction to the direction of plowing, which may hinder the stalk-and-plow crops from being raked into the communication port side. For this reason, when the moving speed (vehicle speed) of the airframe increases, there is a problem that stem and crop crops (especially wheat) harvested in the harvested stem and trap gathering space stay and are not scraped into the feeder house.

  Then, an object of this invention is to provide the combine provided with the rake auger which can rake up a shoot crop more firmly.

The invention described in claim 1
In the combine where the harvested stalk crops are raked into the feeder house with a rake auger and taken into the threshing section through the feeder house,
The take-up auger has a cylindrical auger body with its axis lined in the horizontal direction in the grain header so that it can rotate, and the left and right spiral conveying pieces spiral on the outer surface of the auger body. And a space between the inner ends of the spiral conveying pieces to form a harvested stalk and culm collection space where the harvested stalk and crops are collected.
The mowing stalk gathering space is formed in the communication port where the grain header and the feeder house communicate with each other in the longitudinal direction,
In the part of the outer peripheral surface of the auger main body in which the cutting stalk gathering space is formed, a plurality of retractable type scraping fingers and a fixed type scraping body are disposed,
The scrambling body is characterized in that it is formed in a comb shape by projecting a large number of bar-shaped projecting pieces spaced from the outer peripheral surface of the auger body in the axial direction.

  In the first aspect of the present invention, a plurality of retractable scraping fingers and a fixed scraper are arranged on the outer peripheral surface portion of the auger main body in which the cutting stalk gathering space is formed. Since the body is formed in a comb shape with a large number of rod-shaped protruding pieces protruding from the outer peripheral surface of the auger body in the axial direction, the scalpel fingers and the comb-shaped scrambling body cooperate Then, the stalk-and-crot crop is raked into the feeder house and stabbed into the feeder house. Therefore, even if the moving speed (vehicle speed) of the airframe increases, the stem and crop crops (particularly wheat) gathered in the harvest stem and stem gathering space are smoothly and reliably stirred into the feeder house. As a result, it is possible to prevent stalk and stalk crops from staying in the cut stalk and culm collection space.

Invention of Claim 2 is invention of Claim 1, Comprising:
The protruding piece of the scraper is characterized by being inclined leftward and / or rightward in a front view.

  In the invention of claim 2, since the protruding piece of the scraper is inclined to the left side and / or the right side in the front view, the stem culm crops gathered in the cutting stalk culm collection space stand upright. Even in the posture or the recumbent posture, the protruding pieces in the inclined posture are engaged with each other in a wide and steady manner in the right and left directions. Therefore, regardless of the posture of the stem and culm crops gathered in the harvesting stalk and culm collection space, the stalk and culm crops are smoothly and reliably squeezed into the feeder house by the scraping fingers and the scraped body. . As a result, it is possible to prevent stalk and stalk crops from staying in the cut stalk and culm collection space.

Invention of Claim 3 is invention of Claim 1 or 2, Comprising:
The protruding piece of the scraper is provided with a receding angle with respect to the rotation direction of the auger body.

  In the invention of claim 3, since the projecting piece is provided with a receding angle with respect to the rotation direction of the auger body, the working angle of each projecting piece when acting on the stem-and-cropping crop is an acute angle, It is possible to prevent the stem and stalk crop from being wound around each protruding piece.

Invention of Claim 4 is invention of any one of Claims 1-3, Comprising:
The protruding piece of the scraper is characterized in that the protruding height protruding from the outer peripheral surface of the auger body is set lower than the protruding height of the left and right spiral conveying pieces.

  In the invention according to claim 4, since the protruding height of the protruding piece protruding from the outer peripheral surface of the auger body is set lower than the protruding height of the left and right helical conveying pieces, the left and right helical conveying pieces interfere with each other. The protruding piece does not interfere with the grain header that is formed so as not to occur. Therefore, it is possible to prevent the grain header and the projecting piece from being damaged by the interference.

  According to the present invention, since the scraping fingers and the comb-shaped scratching body cooperate to scratch the stem-and-crochet crop, the stem-and-stalk crop is firmly scraped into the feeder house. Even if the speed (vehicle speed) increases, the stem crops (particularly wheat) gathered in the harvest stem gathering space are smoothly and reliably stirred into the feeder house. As a result, it is possible to prevent stalk and stalk crops from staying in the cut stalk and culm collection space.

The left view of the combine which shows this embodiment. The right view of the said combine. FIG. The II sectional view taken on the line of FIG. FIG. Plane explanatory drawing of a take-in auger. Plane explanatory drawing (a) of a scratched body, front explanatory drawing (b) of a scratched body, and side explanatory diagram (c) of a scratched body. Plane explanatory drawing (a) of the scratching body as a modification, Front explanatory drawing (b) of the scratching body as a modification, Side explanatory drawing (c) of the scratching body as a modification. Explanatory drawing of the power transmission mechanism which a cutting part comprises. Side surface explanatory drawing of a take-in auger. The conceptual diagram of the transmission structure of a combine.

  Embodiments of the present invention will be described below with reference to the drawings. A shown in FIG. 1 and FIG. 2 is a normal combine as a harvesting machine (hereinafter simply referred to as “combine”) in which the entire amount of crops in the harvested field is scraped into a feeder house by a scraping auger. It is.

[Schematic description of overall combine structure]
The combine A has the cutting part 2 attached to the front end part of the traveling machine body 1 capable of self-running so as to be movable up and down.

  As shown in FIGS. 1 and 2, the traveling machine body 1 has a machine body frame 11 installed between a pair of left and right traveling units 10 and 10. And on the left side of the machine body frame 11, a threshing portion 12 for threshing the side portion of the harvested cereal head and a sorting portion 13 for sorting the threshed grain are arranged in the upper and lower stages. A dust exhaust port 14 for discharging sawdust and the like to the field outside the machine is opened rearward. Further, on the right side of the machine body frame 11, a driving unit 15 that performs a driving operation is disposed in the front part, and behind that, a grain that stores grains (fine grains) selected by the selecting unit 13 is stored. The storage part 16 is arrange | positioned and the grain carrying-out part 17 which carries out the grain stored by the grain storage part 16 to the exterior is provided in the last part. Below the rear part of the operation unit 15, an engine 18 or the like as a prime mover unit serving as a power source is disposed.

  The mowing unit 2 includes a rectangular cylindrical feeder house 19 whose axis is directed in the front-rear direction, a horizontally long bucket-shaped grain header 21 that communicates with a front end opening 20 (see FIG. 3) of the feeder house 19, and a grain header. The clipper-shaped cutting blade device 3 disposed at the front lower edge of 21, a pair of left and right weed bodies 22, 22 formed by extending forward from the left and right front parts of the grain header 21, And a take-up reel 23 disposed on the front upper side.

  The rear end portion of the feeder house 19 pivotally supports a reaping input shaft 65 (feeder house conveyor shaft), which will be described later, with the horizontal axis directed to the front portion of the threshing portion 12, and the lower surface portion of the feeder house 19 and the body frame 11. The lifting / lowering cylinder 24 is interposed between the front end of the lifting / lowering cylinder 24 and the lifting / lowering cylinder 24 is expanded and contracted, whereby the cutting portion 2 can be lifted and lowered by using the cutting input shaft 65 as a lifting / lowering fulcrum.

  A feeder conveyor 25 is disposed in the feeder house 19, and a take-up auger 26 (platform auger) is pivoted in the grain header 21 so as to be rotatable about a horizontal axis. The take-up reel 23 is pivoted between the distal end portions of a pair of left and right reel support arms 23a, 23a pivotally supported by the grain header 21 so as to be rotatable about an axis in the left-right direction. The tip of a certain grain candy is continuously driven toward the take-up auger 26 while rotating. The operation parts of the respective parts described above are configured to be interlocked with the engine 18 via respective interlocking mechanisms to be described later and to operate appropriately.

  In the combine A comprised in this way, in the agricultural field, the cutting part 2 is raised until it reaches a desired ground height (cutting position of the corn that is raised), and the traveling machine body 1 is driven in that state. By doing so, the cereal that is napped is weeded by the weeds 22 and 22. The tip part of the cereal that has been weeded is cut by the cutting blade device 3 from the middle part of the cereal while being scraped by the scraping reel 23. The tip side portion of the corn that has been cut at a desired cutting position is scraped into the grain header 21 by the scraping auger 26 and supplied to the threshing section 12 through the feeder house 19 by the supply conveyor 25. The tip side part of the cereal supplied to the threshing unit 12 is threshed by the threshing unit 12, and the grain threshed by the threshing unit 12 is subjected to a sorting process by the sorting unit 13. The grain (clean grain) subjected to the sorting process by the sorting unit 13 is stored in the grain storage unit 16. The grain stored in the grain storage unit 16 is appropriately carried out of the machine by the grain carrying-out unit 17. Moreover, the sawdust etc. which were separated from the grain by the threshing unit 12 are discharged from the dust outlet 14 to the field outside the machine.

[Description of the structure of the biting auger]
As shown in FIGS. 3 to 6, the take-up auger 26 includes a rotary support shaft 27 having an axis line in the left-right direction via a bearing 47 such as a bearing between the left and right side walls 21 b, 21 a of the grain header 21. It is horizontally mounted around the axis. A cylindrical auger body 28 is concentrically attached to the outer periphery of the rotation support shaft 27.

  On the left side of the outer peripheral surface of the auger main body 28, a spiral blade-shaped left spiral conveying piece 29 that conveys the harvested cereals to the right side protrudes, while on the right side of the outer peripheral surface of the auger main body 28 the mowing harvester A right-hand spiral conveying piece 30 having a spiral blade shape for conveying left cereal grains to the left is provided. Between the conveyance end portion of the left spiral conveyance piece 29 and the conveyance termination portion of the right spiral conveyance piece 30, a cut stalk and culm collection space 31 in which the harvested stalk and crop crops are collected is formed on the outer peripheral surface of the auger body 28. It is formed along the cylinder. Moreover, the cutting stalk gathering space 31 is formed to be positioned immediately before the front end opening 20 of the feeder house 19 and is aligned with the front end opening 20 in the front-rear direction. The front end opening 20 is a communication port through which the grain header 21 and the feeder house 19 communicate.

  In the mowing stem collecting space 31, a plurality of pairs of left and right raked fingers 33, 33, which are straight rod-like raked protrusions, are spaced around the circumference of the auger body 28 (in this embodiment, , Four pairs). In the auger main body 28, a retracting mechanism 32 is disposed, and the proximal end portion of the take-in finger 33 is interlocked and connected to the retracting mechanism 32. The intrusion mechanism 32 causes the take-in finger 33 to intermittently protrude from the auger body 28 in the radial direction (radial direction of the auger body 28).

  That is, the retracting mechanism 32 is operated in conjunction with the pivoting operation of the auger body 28 to cause the take-up fingers 33 to protrude from the auger body 28 at the upper peripheral surface and the front surface of the auger main body 28, and In the lower part of the peripheral surface and the rear part of the peripheral surface, the take-in finger 33 is operated to be immersed in the auger body 28. At this time, the take-in finger 33 protrudes to the maximum extent from the auger body 28 at a position facing forward, and is inserted into the auger body 28 at a position facing backward.

  Then, each of the scraping fingers 33 projecting from the pivoting auger body 28 acts to cross the cutting stalks gathered in the cutting stalk gathering space 31 and further lowers the cutting stalks further downward. Is rotated and moved rearward, and a cutting pedicle stick is scraped into the feeder house 19 from the front end opening 20. The take-up auger 26 is rotated in a rotation direction R that is counterclockwise in FIG. 4 that is a left side view. Further, the maximum protruding width of the scraping finger 33 protruding from the peripheral surface of the auger body 28 is slightly larger than the protruding width of the left and right spiral conveying pieces 29 and 30 protruding from the peripheral surface of the auger body 28. .

[Description of Characteristic Configuration of this Embodiment]
A characteristic configuration of the present embodiment will be described with reference to FIGS. In other words, as described above, the take-up auger 26 has a cylindrical auger main body 28 with its axis lined in the left-right direction rotatably mounted in the grain header 21. On the outer peripheral surface of the auger main body 28, a left spiral conveyance piece 29 and a right spiral conveyance piece 30 are formed to project. And between the inner ends of the spiral conveying pieces 29, 30, there is formed a harvested stalk and straw collecting area 31 in which the harvested stem and straw crops are gathered. The cutting stalk gathering space 31 is formed in the front end opening 20 as a communication port through which the grain header 21 and the feeder house 19 communicate with each other in the front-rear direction. On the outer peripheral surface of the auger main body 28 where the cutting stalk gathering space 31 is formed, a plurality of retractable type scissors fingers 33 and a fixed type scoring body 40 are arranged.

  The scraper 40 is formed in a comb shape by projecting a large number of rod-shaped projecting pieces 42 from the outer peripheral surface of the auger main body 28 at intervals in the axial direction thereof. The protruding piece 42 of the scraper 40 is inclined leftward and / or rightward (leftward in the present embodiment) in a front view. The protruding piece 42 of the scraping body 40 is provided with a receding angle θ1 with respect to the rotation direction (counterclockwise as viewed from the left side) R of the auger body 28. The protruding piece 42 of the scraping body 40 is set such that the protruding height H1 from the outer peripheral surface of the auger body 28 is lower than the protruding height H2 of the left and right spiral conveying pieces 29 and 30.

  In the scraping auger 26 configured in this manner, a plurality of retractable scraping fingers 33 and a stationary scraping body 40 are formed on the outer peripheral surface portion of the auger main body 28 in which the cutting stalk collecting space 31 is formed. And the scraper 40 is formed in a comb shape by projecting a large number of rod-shaped projecting pieces 42 from the outer peripheral surface of the auger body 28 in the axial direction thereof. And the comb-shaped scraping body 40 cooperate with each other to cause a stinging action on the stem-and-crochet crop, so that the stem-and-stalk crop is steadily scraped into the feeder house 19. Therefore, even if the moving speed (vehicle speed) of the machine body is increased, the stem and crop crops (particularly wheat) gathered in the harvested stem and stem gathering space 31 are smoothly and reliably stirred into the feeder house 19. As a result, it is possible to prevent the stalk and stalk crops from staying in the cut stalk and culm collection space 31.

  Since the protruding piece 42 of the scraper 40 is inclined leftward and / or rightward (leftward in the present embodiment) in a front view, the protruding piece 42 is wide in the left-right direction and can have a high protruding height. . For this reason, even if the stem and culm crops gathered in the cutting stalk and culm gathering space 31 are in the standing posture or the recumbent posture, the stalk and culm crops gathered in such a posture have the protruding pieces in the inclined posture. Engage steadily. Therefore, regardless of the posture of the culm crops collected in the cut stalk culm collection space 31, the culm crops can be smoothly and reliably fed into the feeder house 19 by the scraping fingers 33 and the scraped bodies 40. Scratched into. As a result, it is possible to prevent the stalk and stalk crops from staying in the cut stalk and culm collection space 31.

  Since the projecting piece 42 is provided with the receding angle θ1 with respect to the rotation direction R of the auger body 28, the operating angle of each projecting piece 42 when the stalk action is applied to the stalk crop becomes an acute angle. It is possible to prevent the stem and stalk crop from being wound around 42.

  Since the protruding height H1 of the protruding piece 42 protruding from the outer peripheral surface of the auger body 28 is set lower than the protruding height H2 of the left / right helical conveying pieces 29, 30, the left / right helical conveying pieces 29, The protruding piece 42 does not interfere with the grain header 21 formed so that 30 does not interfere. Accordingly, it is possible to prevent the grain header 21 and the projecting piece 42 from being damaged by the interference.

[More Specific Description of Characteristic Configuration of Present Embodiment]
(Description of the structure of the scraper)
The configuration of the scraper 40, which is a characteristic configuration of the above-described embodiment, will be described more specifically with reference to FIGS. That is, in the portion of the auger body 28 in which the cutting stalk gathering space 31 is formed, a pair of left and right scraping fingers 33, 33 are arranged around the circumference of the auger body 28 at regular intervals. It is arranged in pairs. The auger body 28 is provided with four scrapers 40 that are positioned between the scraping fingers 33 adjacent to the periphery of the auger body 28. In addition, the scrapers 40 are arranged so as to be displaced from each other in the left-right direction.

  The scraper 40 has a narrow plate-like attachment piece 41 extending in the left-right direction, and a large number (12 in this embodiment) projecting from the upper surface of the attachment piece 41 with a certain interval in the extension direction. The protruding piece 42 is formed. Four attachment holes 43 are formed in the attachment piece 41 at intervals in the extending direction. The attachment piece 41 is attached to the outer peripheral surface of the auger main body 28 via the attachment holes 43 with attachment bolts 44. The protruding piece 42 is formed with a rod-like attachment base 42a having an axis in a direction orthogonal to the left-right direction, which is the extending direction of the attachment piece 41, and an upwardly rising axis from the attachment base 42a. It is integrally formed from the rod-shaped protrusion 42b. Each attachment base 42 a is integrally attached to the upper surface of the attachment piece 41 by welding. Each protrusion 42b is tilted to the left side in a parallel state when viewed from the front, and is provided with a tilt angle θ2. In the present embodiment, the tilt angle θ2 is formed at 45 degrees. And each protrusion part 42b is provided with receding angle (theta) 1 with respect to the rotation direction R of the auger main body 28 by left side view. W is a scratching width of each protrusion 42b, and the scratching width W is a projection width of the protrusion 42b on the outer peripheral surface of the auger body 28, and is concentrated in the cutting stalk collecting space 31. This is the working width in which the projecting portion 42b acts on the stalk and crop.

  In the scoring body 40 configured as described above, the tilting angle θ2 of 45 degrees toward the left side is provided in each projecting portion 42b, so that the scrambling width W and the projecting height H1 can be optimally ensured. Therefore, each protrusion 42b can be effectively raked into the stem and culm crops collected in the cut stalk and culm collection space 31. As a result, the stalk and culm crops collected in the cut stalk and culm collection space 31 are steadily carried into the feeder house 19 through the front end opening 20.

  At this time, the protruding height H1 of the protruding piece 42 protruding from the outer peripheral surface of the auger body 28 is set to be lower than the protruding height H2 of the left and right spiral conveying pieces 29 and 30. Therefore, each protrusion 42b does not interfere with the grain header 21. Moreover, since each protrusion 42b is provided with a receding angle θ1 with respect to the rotation direction R of the auger main body 28, the operating angle of each protrusion 42b when acting on the stem-and-crops crop is an acute angle. In addition, it is possible to prevent the stem-and-crops crop from being wound around each protrusion 42b. Further, as described above, the respective scissors 40 are disposed so as to be displaced from each other in the left-right direction, so that the protrusions 42b of the scissors 40 adjacent to each other in the circumferential direction of the auger body 28 It does not match the direction. Therefore, the protruding portion 42b of any one of the scissors 40 can be squeezed into the stalk crop so that the stalk crop can be squeezed into the feeder house 19.

(Description of the structure of the scraper as a modification)
Next, a configuration of a scraper 40A as a modification will be described with reference to FIG. That is, the modified scraper 40A has the same basic structure as the aforementioned scraper 40, but the left half of the six protruding portions 42b are parallel to each other in the front view. It is different in that the tilt angle θ2 is tilted to provide the tilt angle θ2, while the tilt angle θ2 is tilted to the right in the parallel state.

  In the scraper 40A configured as described above, the six working portions 42b in the left half form a scratching action width W toward the left side, while the six projecting portions 42b in the right half serve to the right. A scraping action width W is formed toward the right side. That is, the scraping action width W is uniformly formed in both the left and right directions. Therefore, it is possible to make the protruding portion 42b having the same width W in the left and right directions to be steadily raked into the stalk crops retained in the cutting stalk collecting space 31.

(Description of the structure of the intake protrusion)
The left and right spiral conveying pieces 29 and 30 are provided with projecting projecting pieces 45 and 46 as shown in FIGS. That is, the end portions 29a and 30a of the left and right spiral conveying pieces 29 and 30 are arranged immediately in front of the front end opening 20 of the feeder house 19, and are respectively within the left and right widths of the front end opening 20 in a front view. Terminal portions 29a and 30a are arranged. A plurality of intake protrusions 45 and 46 are provided so as to protrude from the end portions 29a and 30a. In the present embodiment, two intake projecting pieces 45 project from the end portion 29a of the left spiral conveying piece 29 with a constant interval (equal pitch interval) in the extending direction. On the other hand, at the end portion 30a of the right spiral conveying piece 30, five intake projecting pieces 46 project from the extending direction at a constant interval (equal pitch interval).

  The take-up protrusions 45 and 46 are formed in a square plate shape extending in the radial direction of the auger body 28, and are provided with rearward inclined end surfaces 45a and 46a by notching the tip corners facing the rotation direction R in a straight line. Thus, it is formed in a pentagonal plate shape. Each take-up protrusion 45, 46 is attached to the back face of each end portion 29a, 30a in a superposed state by means of mounting bolts 48, 49, and the leading end 45b, 46b of each take-up protrusion 45, 46 is attached to the auger body. The end portions 29a and 30a protrude in the radial direction of 28.

  In each of the intake projecting pieces 45 and 46 configured in this manner, the tip end portions 45b and 46b protruding from the end portions 29a and 30a are stalk crops that are retained in the front end opening 20 of the feeder house 19. , It can be taken into the feeder house 19 steadily. At this time, since a plurality of the intake projecting pieces 45 and 46 are provided at equal pitch intervals, they can be hooked evenly on the stalk crop. Each tip 45b, 46b is provided with rearwardly inclined end surfaces 45a, 46a on the side facing the rotation direction R, so that the stalk crops can be hooked without damaging them. It can be taken into the feeder house 19 by acting.

(Description of the drive transmission mechanism of the take-in reel)
As shown in FIG. 10, the right end portion of the rotation support shaft 27 extends from the right side wall 21a of the grain header 21 so as to protrude rightward, and the auger passive sprocket 35 and the reel drive sprocket are extended to the extension portion 27a. 36 is attached concentrically. 21b is a left side wall.

  As shown in FIG. 10, the auger passive sprocket 35 is linked to a ninth transmission mechanism 126 that is a scraping auger transmission portion of a reaping portion transmission mechanism described later. That is, the ninth transmission mechanism 126 is formed by winding an auger transmission chain 141 between an auger drive sprocket 140 and an auger passive sprocket 35 provided on a cutting counter shaft 125 described later. A tension adjusting unit 142 adjusts the tension of the auger transmission chain 141. Then, the rotational force is transmitted to the cutting counter shaft 125 → the auger drive sprocket 140 → the auger transmission chain 141 → the auger passive sprocket 35 → the extended portion 27 a and the rotary support shaft 27 → the auger body 28.

  In addition, as shown in FIG. 10, a tenth transmission mechanism 150 and an eleventh transmission mechanism 127, which are a scraping reel transmission section of a reaping section transmission mechanism, which will be described later, are linked to the reel drive sprocket 36. That is, the tenth transmission mechanism 150 is formed by winding the first reel transmission chain 152 between the reel drive sprocket 36 and the first reel passive sprocket 151. The eleventh transmission mechanism 127 includes a second reel drive pulley 153 that is coaxially attached via a first reel passive sprocket 151 and a relay shaft 156, and a second reel passive pulley that is attached to the reel support shaft 157 of the take-up reel 23. A second reel transmission belt 155 is wound around the belt 154.

  The second reel drive pulley 153 has a split pulley structure that can adjust the rotation speed of the take-up reel 23 steplessly. A midway portion of the tension arm 56 extending in the vertical direction is pivotally supported in the midway portion of the right reel support arm 23a via an arm support shaft 55 having an axis line in the left-right direction. A first tension pulley 57 is attached to the arm support shaft 55 coaxially with the middle portion of the tension arm 56. A second tension pulley 58 is attached to the upper end of the tension arm 56. The first tension pulley 57 and the second tension pulley 58 have a meandering portion of the second reel transmission belt 155 wound in a meandering state. A tension spring 59 is interposed between the lower end of the tension arm 56 and the tenth transmission mechanism cover 162 via a spring locking rod 60.

  With this configuration, a constant tension can be applied to the second reel transmission belt 155 by the tensile biasing force of the tension spring 59. Further, by adjusting the split interval of the second reel drive pulley 153 having a split pulley structure, the rotational speed of the take-up reel 23 can be adjusted steplessly. At this time, if an abnormal load is applied to the take-up reel 23, the second reel transmission belt 155 slips on the peripheral surfaces of the pulleys 153, 154, 57, 58, so that the parts such as the take-up reel 23 are damaged. Can be prevented.

  Then, the auger passive sprocket 35 → the extending portion 27a / the rotation support shaft 27 → the reel driving sprocket 36 → the first reel transmission chain 152 → the first reel passive sprocket 151 → the relay shaft 156 → the second reel driving pulley 153 → the second reel. The rotational force is transmitted to the transmission belt 155 → the second reel passive pulley 154 → the reel spindle 157 → the take-in reel 23. 160 is an eighth transmission mechanism cover that covers the eighth transmission mechanism 124, 161 is a ninth transmission mechanism cover that covers the ninth transmission mechanism 126, and 162 is a tenth transmission mechanism cover that covers the tenth transmission mechanism 150.

[Specific description of configuration of traveling aircraft]
As shown in FIG. 1, a pair of left and right cutting posts (not shown) are erected on the front end of the body frame 11, and both ends of the cutting input shaft 65 are freely rotatable on both cutting posts. It is pivotally supported. A forward / reverse switching case 66 is attached to the left harvesting column, and the forward / reverse switching case 66 has a cutting input shaft 65 and a forward / reverse transmission shaft 51 horizontally mounted on the same axis. The rear ends of the feeder house 19 are rotatably supported by the left and right cutting posts through a cutting input shaft 65. In addition, a beater 71 for feeding the harvested culm is pivotally supported between the left and right harvesting columns via a beater shaft 70.

  As shown in FIG. 1, the harvested culm thrower beater 71 is provided on the feed end side of the supply conveyor 25 and is fed into the handling port of the threshing unit 12 by the harvested culm thrower beater 71. A handling cylinder 72 is rotatably supported in the handling chamber of the threshing unit 12 via a handling cylinder shaft 75. On the lower side of the handling cylinder 72, a receiving net 73 for allowing the grains to leak is stretched. Note that a spiral screw blade-shaped intake blade 74 protrudes radially outward from the outer peripheral surface of the front portion of the barrel 72.

  As shown in FIG. 1, the sorting unit 13 is provided with a grain sorting mechanism 77 arranged below the receiving net 73. The grain sorting mechanism 77 includes a rocking sorter 78 for specific gravity sorting having a grain pan, chaff sheave, Glen sheave, Strollac, and the like, and a tang fan 76 that supplies sorting wind to the rocking sorter 78. The threshing that has been threshed by the handling cylinder 72 and leaked from the receiving net 73 is separated from the grain (the most important one such as a refined grain) by the specific gravity sorting action of the swing sorter 78 and the wind sorting action of the Kara fan 76. It is configured such that it is sorted out into a mixture of grain and straw (second thing such as grain with branches), and sawdust and the like.

  Below the swing sorter 78, a first conveyor mechanism 79 and a second conveyor mechanism 80 as a grain sorting mechanism 77 are provided. The grain (first thing) dropped from the swing sorter 78 by the sorting of the swing sorter 78 and the Kara fan 76 is stored in the grain storage unit 16 by the first conveyor mechanism 79 and the lifting conveyor 81. . The mixture of grain and straw (second product) is returned to the sorting start end side of the swing sorting plate 78 via the second conveyor mechanism 80 and the second reduction conveyor 82 and is re-sorted by the swing sorting plate 78. The Waste dust and the like are discharged from the dust outlet 14 at the rear of the traveling machine body 1 to the field.

  As shown in FIGS. 1 and 2, the operation unit 15 includes a front operation column 89, a side operation column 90, and a driver seat 91 on which an operator is seated. A steering lever 92 that changes the course of the traveling machine body 1 is disposed in the front operation column 89. In the side operation column 90, a shift lever 93 and the like for switching the moving speed of the traveling machine body 1 are arranged. Further, a roof 95 for awning is attached to the upper side of the operation unit 15 via a roof support column 94.

  As shown in FIGS. 1, 2, and 11, the traveling unit 10 has driving wheels 97 and driven wheels 98 attached to the front and rear portions of the traveling frame 96, and a crawler belt 99 is wound around these moving wheels. A mission case 100 is interposed between the drive wheels 97 of the pair of left and right traveling units 10 and 10 via traveling drive shafts 101 and 101. The mission case 100 includes a traveling hydraulic pump and a hydraulic motor. A hydraulic continuously variable transmission 102 for shifting is provided.

[Explanation of combine transmission structure]
Next, the transmission structure of the combine A will be described with reference to FIG. That is, to the drive shaft 110 provided in the engine 18, a tang fan fan shaft 112 that pivotally supports the tang fan fan 76 is linked and connected via the first transmission mechanism 111. The first conveyor shaft 114 is linked to the Kara fan support shaft 112 via a second transmission mechanism 113. A second conveyor shaft 116 is linked to the first conveyor shaft 114 via a third transmission mechanism 115. A swing sorter operating shaft 118 is linked to the second conveyor shaft 116 via a fourth transmission mechanism 117.

  A threshing countershaft 120 is linked to the Kara fan support shaft 112 via a fifth transmission mechanism 119. A handling cylinder shaft 75 is linked to the threshing counter shaft 120 via a gear case 121. The beater shaft 70 is linked to the threshing counter shaft 120 via the sixth transmission mechanism 122. A forward / reverse transmission shaft 51 is linked to the beater shaft 70 via a seventh transmission mechanism 123. 69 is a beater output sprocket, and 83 is a beater input sprocket.

  Further, the cutting input shaft 65 linked to the forward / reverse transmission shaft 51 via the forward / reverse switching case 66 is linked to the supply conveyor 25, and the cutting counter shaft 125 is linked to the mowing counter shaft 125 via the eighth transmission mechanism 124. doing. The cut counter auger 26 is linked to the cutting counter shaft 125 via a ninth transmission mechanism 126, and the scraping reel 23 is linked to each other via a tenth transmission mechanism 150 and an eleventh transmission mechanism 127. The movable cutting blade body 3a of the cutting blade device 3 is interlocked and connected through the cutting blade transmission mechanism 128.

  An input shaft 130 of the hydraulic continuously variable transmission 102 is linked to a drive shaft 110 provided in the engine 18 via a twelfth transmission mechanism 129. A cooling fan 132 is linked to the engine 18 via a fan drive shaft 131. The fan drive shaft 131 is provided in the grain storage unit 16 and the grain carry-out unit 17 via a conveyor transmission mechanism 133, respectively. The carry-out conveyors 134 and 135 are linked to each other.

A Combine 1 Traveling machine body 2 Cutting part 20 Front end opening 26 Stake auger 27 Rotating support shaft 31 Cutting stalk gathering space 40 Scratching body 41 Mounting piece 42 Projection piece θ1 Retraction angle θ2 Tilt angle

Claims (4)

In the combine where the harvested stalk crops are raked into the feeder house with a rake auger and taken into the threshing section through the feeder house,
The take-up auger has a cylindrical auger body with its axis lined in the horizontal direction in the grain header so that it can rotate, and the left and right spiral conveying pieces spiral on the outer surface of the auger body. And a space between the inner ends of the spiral conveying pieces to form a harvested stalk and culm collection space where the harvested stalk and crops are collected.
The mowing stalk gathering space is formed in the communication port where the grain header and the feeder house communicate with each other in the longitudinal direction,
In the part of the outer peripheral surface of the auger main body in which the cutting stalk gathering space is formed, a plurality of retractable type scraping fingers and a fixed type scraping body are disposed,
The combiner is characterized by having a comb-like shape in which a large number of bar-shaped projecting pieces are projected from the outer peripheral surface of the auger body at intervals in the axial direction thereof.   The combiner according to claim 1, wherein the protruding piece of the scraper is inclined leftward and / or rightward in a front view.   The combine according to claim 1 or 2, wherein the protruding piece of the scraper is provided with a receding angle with respect to the rotation direction of the auger body.   The protruding piece protruding from the outer peripheral surface of the auger body has a protruding height set lower than the protruding height of the left / right spiral conveying piece. 1. Combine according to item 1.

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