JP5273788B2 - Combine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a combine harvester simply reducing production cost of a grain culm raising apparatus 31 having a different number of reaping rows, and improving the maintenance operation efficiency of the grain culm raising apparatus 31 having the different number of reaping rows. <P>SOLUTION: The combine harvester includes: a traveling machine body 1 having a traveling part 2 operating by an engine 20; reaping apparatus 3; and threshing apparatus 5. The reaping apparatus 3 is composed so as to raise grain culms planted stand in a field by the grain culm raising apparatus 31, cut plant feet of the grain culms with a reaping blade apparatus 32, and transport the grain culms to the threshing apparatus 5 with a grain culm transporting apparatus 33. A plurality of raising cases 42 for the plurality of rows are installed transversely side by side in the grain culm raising apparatus 31. In the combine harvester, a plurality of gear cases 41 respectively installed on the rear side of the plurality of raising cases 42 for the plurality of rows, and a plurality of driving input cases 40 respectively connecting each gear case 41 are disposed on the upper end side of each raising case 42 to support the plurality of driving input cases 40 on a reaping upper frame 121 of the reaping apparatus 3, and composed so as to tighten each gear case 41 securely to each driving input case 40 with each case-connecting bolt 142. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to a combine that harvests grains by threshing the harvested corn straw with a threshing device while harvesting the unmilled grain moth on the field by a reaping device, and more specifically, causes an uncut cereal grain on the field. The present invention relates to a combine equipped with a grain raising apparatus.

The conventional combine harvester is configured to harvest uncut mushroom cereals in the field by a reaping device arranged to be able to move up and down on the front side of the traveling machine body, and to thresh the harvested cereals by a threshing device and collect the grains (See Patent Document 1). In addition, it is also known to provide a front weeding plate of the reaping device so as to be pivotable forward from the weeding position (see Patent Document 2).
JP-A-6-335314 JP-A-6-11423

  In patent document 1, it is comprised so that cleaning of a corn straw conveyance apparatus etc. can be performed easily by moving the downward side upwards by using an upper transmission part as a fulcrum, and raising the corn straw raising apparatus which raises the uncut corn straw of a field However, when the grain raising device is configured in a state where a plurality of raising cases for multi-row mowing are integrally connected, it is necessary to specially design and manufacture the grain raising device with different number of cutting lines Therefore, it is not possible to easily reduce the manufacturing cost of the grain raising apparatus having different number of cutting lines. Moreover, there existed a problem that the maintenance workability | operativity of the grain raising apparatus from which the number of cuttings differs could not be improved.

  An object of the present invention is to provide a combine that can easily reduce the manufacturing cost of a grain raising apparatus with different number of cutting lines and can improve the maintenance workability of the grain raising apparatus with different number of cutting lines.

In order to achieve the above object, the combine of the invention according to claim 1 includes a traveling machine body including a traveling unit that is operated by an engine, a reaping device, and a threshing device, and the reaping device is planted in a farm field. The cereal is caused by a cereal pulling device, the root of the cereal is cut by a cutting blade device, and the cereal is conveyed to the threshing device by the cereal conveying device. In a combine in which a plurality of multi-raising cases are provided side-by-side on the pulling-up device, a plurality of gear cases provided on the back side of the plurality of multi-raising cases and a plurality of drives for connecting the gear cases, respectively. An input case is disposed on an upper end side of each pulling case, the plurality of drive input cases are supported on a cutting upper frame of the cutting device, and each gear case is connected to a case connecting bolt on each driving input case. Configured to conclude, the passed through the Pick drive shaft to the driving input case, and Pick the cause through a bevel gear mechanism to the transmission shaft in the gear case and configured to connect the drive shaft, wherein A case connection bolt is passed through one end side flange of the drive input case and one end side flange of the gear case, a case connection bolt is passed through the other end side flange of the gear case, and the case is connected to the other end side flange of the drive input case. The connecting bolt is configured to be screwed, and the case connecting bolt is made to pass through the mounting holes of the flanges when the lower end side is turned upward about the upper end side of the pulling case. It is what you are doing .

The invention according to claim 2 is the combine according to claim 1, wherein a plurality of multiple weed frames and weed bodies are provided side by side on the front side of each pulling case, and each weed The elevating case is configured to be rotatable around the elevating drive shaft in the drive input case in a state where the respective weed bodies are separated from the frame and the fastening of the case connecting bolt is released.

According to the first aspect of the present invention, the vehicle includes a traveling machine body having a traveling unit that is operated by an engine, a reaping device, and a threshing device, and the reaping device raises the cereal that has been planted in a field. It raises with a device, cuts the stock of the cereal with a cutting blade device, is configured to convey the cereal to the threshing device with the cereal conveying device, In a combine provided side by side with a plurality of pulling cases, a plurality of gear cases respectively provided on the back side of the plurality of pulling cases for a plurality of strips, and a plurality of drive input cases respectively connecting the gear cases, It is arranged on the upper end side of each pulling case, is configured to support the plurality of drive input cases on a cutting upper frame of the cutting device, and to fasten each gear case to each driving input case with a case connecting bolt , Said The drive input case is caused to pass through the drive shaft, and the pulling drive shaft in the gear case is connected to the pulling drive shaft via a bevel gear mechanism. A case connecting bolt is passed through one end flange of the gear case, a case connecting bolt is passed through the other end flange of the gear case, and a screw of the case connecting bolt is screwed into the other end flange of the drive input case. When the lower end side is turned upward about the upper end side of the pulling case, the case connecting bolt is inserted through the mounting holes of the flanges. The plurality of pulling cases for cutting and the gear cases can be formed into a unit structure or the like that can be easily disassembled, for example, for each strip. It is possible to easily reduce the manufacturing cost of the grain raising apparatus with different number of cutting lines and to improve the maintenance workability of the grain raising apparatus with different number of cutting lines. That is, a plurality of pulling cases and gear cases (plural pulling units) for multiple strips can be assembled in a state in which a set of the pulling case and the gear case are assembled as a single pulling unit. . The pulling case and the gear case (the pulling unit) can be shared by the cutting devices having different numbers of cutting lines. It is possible to improve the workability in the assembly process of the manufacturing place where a plurality of types of combine is produced and the maintenance workability such as assembly or disassembly of the pulling case in the maintenance service place that handles the multiple types of combine.

Further, since the drive input shafts are caused to penetrate through the drive shafts, and the pulling drive shafts in the gear cases are connected to the lifted drive shafts via bevel gear mechanisms. While the upper frame can easily support the upper end side of the pulling case via the drive input case, for example, the pulling drive shaft having a length corresponding to the number of the pulling strips is provided via the drive input case. Easy to assemble.

Further, a case connecting bolt is passed through one end side flange of the drive input case and one end side flange of the gear case, a case connecting bolt is passed through the other end side flange of the gear case, and the other end side flange of the drive input case is The case connecting bolt is screwed into the case case, and when the lower end side is turned upward about the upper end side of the pulling case, the case connecting bolt is passed through the mounting holes of the flanges. Therefore, it is not necessary to provide a member for lifting and supporting the pulling case. By using the case connecting bolt, the pulling case can be easily supported in the upward rotation posture. Loss of the case connection bolt can be prevented in maintenance work of the cereal carrying device that is performed with the pulling case rotated upward. For example, when the lower end side is rotated upward with the upper end side of the pulling case as the center, the mounting holes and the mounting screw holes of the flanges of the drive input case are connected to the bolt insertion holes of the flanges of the gear case. Since the case connecting bolt can be penetrated, an operator can open the front of the grain feeder by attaching the case connecting bolt with the other hand while lifting the pulling case with one hand. On the other hand, while supporting the posture in which the operator lifts the pulling case with one hand, the pulling case can be lowered by removing the case connecting bolt with the other hand.

According to the second aspect of the present invention, a plurality of multiple weeding frames and weeding bodies are provided side by side on the front side of each pulling case, and each weeding body is taken from each weeding frame. Since the pulling case is configured to be rotatable around the pulling drive shaft in the drive input case in a state where the case connecting bolt is separated and released, the pulling case and the gear case are The raising case can be moved from the grain raising position to the upper non-working position without disassembling. The front side of the cereal conveyance device behind the pulling case can be largely released. Maintenance workability | operativity, such as the said cereal conveyance apparatus, can be improved.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments embodying a combine according to the present invention will be described with reference to the drawings. In the following description, the left side in the forward direction of the traveling machine body 1 is simply referred to as the left side, and the right side in the forward direction is also simply referred to as the right side. The combine of this embodiment is demonstrated with reference to FIG. 1 thru | or FIG. As shown in FIGS. 1 to 4, a traveling machine body 1 supported by a pair of left and right traveling crawlers 2 (traveling portions) is provided. At the front part of the traveling machine body 1, a four-row mowing device 3 for mowing cereals is mounted by a single-acting hoisting hydraulic cylinder 4 so as to be adjustable up and down around the mowing pivot fulcrum shaft 4a. . A threshing device 5 having a feed chain 6 and a grain tank 7 for storing grain after threshing are mounted on the traveling machine body 1 side by side. In addition, the threshing apparatus 5 is arrange | positioned at the left side toward the advancing direction of the traveling body 1, and the Glen tank 7 is arrange | positioned at the right side toward the advancing direction of the traveling body 1 (refer FIG. 3).

  A discharge auger 8 for discharging the grains in the grain tank 7 from the rear to the top of the grain tank 7 is provided. Centering on the vertical auger 8a of the discharge auger 8, the front part of the glen tank 8 can be rotated to the side of the machine body. A driving unit 10 is provided in front of the Glen tank 7 and on the right front of the traveling machine body 1. The driving unit 10 includes an operation device including a step 10a on which an operator gets on, a driver's seat 10b, a steering handle 10c, various operation levers, switches, and the like. An engine 20 as a power source is disposed in the traveling machine body 1 below the driver seat 10b.

  As shown in FIGS. 1 and 2, left and right track frames 21 are arranged on the lower surface side of the traveling machine body 1. The track frame 21 includes a drive sprocket 22 that transmits the power of the engine 20 to the traveling crawler 2, a tension roller 23 that maintains the tension of the traveling crawler 2, and a plurality of track rollers that hold the ground side of the traveling crawler 2 in a grounded state. 24. The driving sprocket 22 supports the front side of the traveling crawler 2, the tension roller 23 supports the rear side of the traveling crawler 2, and the track roller 24 supports the grounding side of the traveling crawler 2.

  As shown in FIG. 1 to FIG. 3, the reaping device 3 includes a four-row culm pulling device 31 that causes uncut cereals in the field and a clipper-type cutting device that cuts the stock of uncut cereals in the field. A cutting blade device 32 and a culm transporting device 33 for transporting the chopped culm from the culm pulling device 31 to the front end (feed start end side) of the feed chain 6 are provided. An uncut grain culm in the field is pulled up by the grain culling pulling device 31, a stock source of the uncut grain culm is cut by the cutting blade device 32, and the harvested corn straw is conveyed to the front end portion of the feed chain 6 by the grain culling pulling device 31. Is done.

  The threshing device 5 includes a handling cylinder 51 for threshing threshing, an oscillating sorting board 52 as an oscillating sorting mechanism for sorting threshing material falling below the handling cylinder 51, and a sorting wind on the oscillating sorting board 52. , A processing fan 54 for reprocessing threshing waste taken out from the rear part of the handling cylinder 51, and a dust exhausting fan 61 for discharging dust at the rear part of the swing sorter 52 to the outside of the machine. It has.

  As shown in FIGS. 1 and 2, an exhaust chain 62 is disposed on the rear end side (feed end side) of the feed chain 6. The waste passed through the feed chain 6 from the rear end side of the feed chain 6 (the grain from which the grain has been threshed) is discharged to the rear of the traveling machine body 1 in a long state, or the rear side of the threshing device 5 After being cut to a suitable length by the waste cutter 63 provided at the front, the paper is discharged to the lower rear of the traveling machine body 1.

  Below the rocking sorter 52 are a first conveyor 55 for picking up the grains (the first sort) selected by the rocking sorter 52, and grains, swarf, and grains with branches. A second conveyor 56 is provided to take out the mixed second selection. In addition, from the front side of the traveling direction of the traveling machine body 1, the first conveyor 55 and the second conveyor 56 are arranged on the upper surface side of the traveling machine body 1 above the rear part of the traveling crawler 2 in a side view.

  The swing sorting board 52 is configured to swing-sort (specific gravity sort) the cereal grains that have fallen below the handling cylinder 51. Grains that fall from the oscillating sorter 52 (the first sort) are removed from the grain by the sorter wind from the tang fan 53 and fall first onto the conveyor 55. A first cereal cylinder 57 extending in the vertical direction is connected to a terminal portion of the first conveyor 55 that protrudes outward from one side wall (right side wall in the embodiment) of the threshing device 5 near the grain tank 7. Yes. The grain taken out from the first conveyor 55 is carried into the Glen tank 7 by a first cereal conveyor (not shown) provided in the first cereal cylinder 57 and collected in the Glen tank 7.

  Oscillating sorter 52 performs second sorting such as grain with branches and branches (reduction-reprocessed product for re-sorting mixed grain and swarf) by swing sorting (specific gravity sorting). 56 is configured to be dropped. The second sorting product taken out by the second conveyor 56 is returned to the upper surface side of the swing sorting board 52 through the second reduction cylinder 58 and the second processing unit 59 and is re-sorted. Further, the dust and dust in the crushed material from the handling drum 51 are discharged from the rear portion of the traveling machine body 1 toward the field by the sorting air from the tang fan 53 and the dust suction and discharge action of the dust fan 61. .

  Next, the structure of the reaping device 3 will be described with reference to FIGS. As shown in FIGS. 6 to 8, the cutting frame 30 of the cutting device 3 includes a cutting input frame 35, which is a cutting rotation fulcrum shaft 4 a, a vertical transmission frame 36, and a horizontal transmission frame 37. A cutting input frame 35 is rotatably supported by a cutting support 34 (see FIG. 1) erected on the front portion of the traveling machine body 1. The cutting input frame 35 is extended in the left-right direction of the traveling machine body 1. A longitudinal transmission frame 36 is extended forward from the cutting input frame 35. A horizontal transmission frame 37 is connected to the front end side of the vertical transmission frame 36. A lateral transmission frame 37 is extended in the left-right direction of the traveling machine body 1.

  As shown in FIGS. 5 and 8, the cutting input frame 35 incorporates a cutting input shaft 35 a to which power from the engine 20 is transmitted. The cutting input shaft 35a rotates around a horizontal axis (cutting rotation fulcrum shaft 4a). A cutting lift hydraulic cylinder 4 is disposed between the vertical transmission frame 36 and the traveling machine body 1. By operating the hydraulic cylinder 4 by a control device (not shown) such as a lifting operation lever, the cutting device 3 (vertical transmission frame 36) is rotated about the cutting rotation fulcrum shaft 4a. As a result, the cutting device 3 (the cutting blade device 32) can be raised and lowered to an arbitrary height.

  As shown in FIGS. 7 to 9, 13, and 15, four weeding frames 38 (for the number of cutting lines) are extended from the lateral transmission frame 37 toward the front. A weeding body 38a is fastened to the front end side of each weeding frame 38 by a weeding bolt 38c. On the left end side of the horizontal transmission frame 37, one pulling input vertical case 39 is erected so as to extend obliquely upward in the forward direction. On the further left end side of the lateral transmission frame 37, a cutting blade drive shaft 49c of the cutting blade drive unit 49 is disposed. That is, the cutting blade drive unit 49 attached to the left end portion of the lateral transmission frame 37 is disposed closer to the outer side of the machine body than the pulling input vertical case 39.

  As shown in FIGS. 7, 9, and 13, the upper end side of the pulling input vertical case 39 is connected to the left end portion of the pulling input horizontal case 40 extending in the left-right direction. In addition, a round pipe-shaped pulling vertical frame 50 is erected on the rightmost weed frame 38. The upper end side of the pulling vertical frame 50 is connected to the right end portion of the pulling input horizontal case 40. The pulling input horizontal case 40 is horizontally extended by the pulling input vertical case 39 and the pulling vertical frame 50 above the upper end of the pulling case 42 in the horizontal direction of the reaping device 3.

  As shown in FIGS. 7, 9, and 13, a speed change case 39 b is provided at a high position on the upper end side of the pulling input vertical case 39 close to the pulling input horizontal case 40. In the pulling input side case 40, the number of pulling drive cases 41 corresponding to the number of cutting lines (four in this embodiment) is the longitudinal direction of the pulling input side case 40 (width direction of the traveling machine body 2). Are lined downward at appropriate intervals. That is, as a pulling input case for driving force input to the pulling case 42 described later, a pulling input vertical case 39 as the cutting frame 30, a pulling input horizontal case 40 as the cutting frame 30, and four pulling driving cases. 41 are arranged.

  As shown in FIG. 5, the grain raising device 31 is provided with four raising cases 42 as a raising mechanism. Each pulling case 42 is provided with a plurality of pulling tines 42a for raising the uncut grain straws that have been weeded by the weeding body 38a. The plurality of pulling tines 42a for one line are arranged at substantially equal intervals in one endless pulling tine chain 42b. The pulling case 42 is disposed behind the weed body 38a. The pulling case 42 is provided in a vertically inclined posture that is long in the vertical direction. The upper end side of the pulling case 42 is connected to the lower end side of the pulling drive case 41. The lower end side of the raising case 42 is connected to the raising support frame 38 b erected on the weeding frame 38.

  The auxiliary pulling tine 71a is detachably installed on the front surfaces of the left and right and central pulling cases 42 so that the uncut cereal grains lying in the field are erected by the auxiliary pulling tine 71a. The auxiliary pulling tine 71 a is provided in the auxiliary pulling case 71. The auxiliary pulling case 71 is attached to the front side of the pulling case 42 as necessary. A driving force is transmitted from the pulling drive case 41 to the auxiliary pulling tine 71a. FIG. 5 shows a state in which the auxiliary pulling case 71 is connected only to the pulling case 42 located on the leftmost side.

  As shown in FIG. 5, the grain feeder 33 is disposed behind the pulling case 42. The grain straw transporting device 33 includes four pieces of star foils 43R and 43L and a take-up belts 44R and 44L that rake the stock side of the uncut grain straw introduced from the pulling case 42 for four pieces, and two pieces on the right side. Right stock transport chain 45R that transports the harvester side of the harvested cereals of the minute and the left strain that joins the stock side of the harvested grain halves of the left two strips to the transport end side of the right stocker transport chain 45R A former transfer chain 45L. Moreover, the grain straw transporting device 33 transports the feed chain 6 from the vertical transportation chain 46 that inherits the stock side of the harvested grain straw for four strips from the right stock transportation chain 45R, and the transportation terminal end of the vertical transportation chain 46. The auxiliary stock former conveyance chain 74 which conveys the stock origin side of the harvested cereals for four strips is provided at the start end.

  Furthermore, as shown in FIG. 5, the grain culm transport device 33 is transported by the right stalk transport tine 47R that transports the stalk tip side of the harvested cereal transported by the right stock transport chain 45R and the left stock transport chain 45L. A left-hand tip transport tine 47L that transports the tip side of the harvested cereal rice bran, and a rear-tip transport tine 75 that transports the tip side of the four chopped grain stalks transported by the vertical transport chain 46. The tip side of the four sown cereal grains harvested by the reaping device 3 is transported from the feed end side of the rear stalk tip transport tine 75 into the handling chamber of the threshing device 5 incorporating the handling barrel 51.

  As shown in FIGS. 5 and 7, the cutting blade device 32 includes two sets of left and right hair clipper-type cutting blades 48R and 48L. Below the weeding frame 38, two sets of left and right hair clipper-type cutting blades 48 </ b> R and 48 </ b> L are provided along the lateral transmission frame 37 in the horizontal width direction of the cutting device 3. The two sets of left and right cutting blades 48R and 48L cut the stock of uncut cereals that have been raked by the four pieces of star foils 43R and 43L and the rake belts 44R and 44L.

  As shown in FIGS. 5, 7, and 8, left and right cutting blade drive units 49 that drive the left and right cutting blades 48 </ b> R and 48 </ b> L independently are provided. The left and right cutting blade drive units 49 are respectively arranged on the upper surface side of the left and right side end portions of the lateral transmission frame 37. Each cutting blade drive unit 49 is disposed on the upper end side of a cutting blade drive shaft 49 c that is connected to the horizontal transmission shaft 37 a of the horizontal transmission frame 37 and a cutting blade drive shaft 49 c that is protruded from the upper surface side of the horizontal transmission frame 37. A crank rod 49a and a crank arm body 49b for connecting cutting blades 48R and 48L to the crank rod 49a are provided. A lateral transmission shaft 37a is connected to the left and right cutting blades 48R and 48L via a crank rod 49a and a crank arm body 49b.

  The left and right cutting blades 48 reciprocate left and right as the crank rod 49a swings. By the left and right cutting blade drive units 49, the left cutting blade 48L and the right cutting blade 48R are reciprocally moved in synchronization with opposite directions. As a result, the vibration (inertial force) of the left and right cutting blades 48 generated by the reciprocating movement of the left and right cutting blades 48 can be offset. The vibration generated by the reciprocating movement of the cutting blade 48 can be reduced.

  As shown in FIGS. 7 and 8, the cutting blade drive unit 49 and the pulling input vertical case 39 are arranged at positions away from the culm transport path of the culm transport device 33. That is, the cutting blade drive shaft 49c and the crank rod 49a are disposed at the left and right ends of the lateral transmission frame 37, respectively. A pulling input vertical case 39 is erected at the left end portion of the lateral transmission frame 37 closer to the body than the left cutting blade drive shaft 49c and the crank rod 49a. That is, the pulling input vertical case 39 is installed on the inner side of the machine body than the cutting blade drive unit 49.

  Next, the drive structure of the reaping device 3 will be described with reference to FIG. As shown in FIG. 5, a cutting input shaft 35 a is inserted into a round pipe-shaped cutting input frame 35. A vertical transmission shaft 36 a is inserted into a round pipe-shaped vertical transmission frame 36. A horizontal transmission shaft 37 a is inserted into a round pipe-shaped horizontal transmission frame 37. One end of the longitudinal transmission shaft 36a is connected to the cutting input shaft 35a. The other end side of the vertical transmission shaft 36a is connected to the horizontal transmission shaft 37a. The driving force from the engine 20 is transmitted to the cutting input shaft 35a. The rotational driving force of the cutting input shaft 35a is transmitted to the horizontal transmission shaft 37a via the vertical transmission shaft 36a.

  As shown in FIG. 5, the pulling input vertical axis 39 a is arranged in the pulling input vertical case 39. One end of the pulling input vertical axis 39a is connected to the horizontal transmission shaft 37a. A speed change case 39 b is provided in the middle of the pulling input vertical case 39. A transmission gear 39c is provided in the middle of the pulling input vertical axis 39a. Further, the pulling input horizontal axis 40 a is arranged in the pulling input horizontal case 40. The pulling input horizontal axis 40a is connected to the other end side of the pulling input vertical axis 39a. The pulling tine drive shaft 41a is disposed in each of the four pulling drive cases 41. The pulling tine drive shaft 41a is connected to the pulling input horizontal shaft 40a.

  Accordingly, the rotational force of the horizontal transmission shaft 37a is transmitted to the pulling tine chain 42b via the pulling input vertical axis 39a, the transmission gear 39c, the pulling input horizontal shaft 40a, and the pulling tine drive shaft 41a. By driving a plurality of pulling tines 42a, an uncut grain culm in the field is set up. In the case where the auxiliary pulling case 71 is provided, the auxiliary pulling case 71 is coupled to the pulling case 42 so that the auxiliary pulling tine 71a is driven by the pulling tine drive shaft 41a.

  As shown in FIG. 5, a right stock drive chain 45R, a right tip transport tine 47R, a right transport drive shaft 72 for driving the right side two-segment star wheel 43R and the scraping belt 44R are provided. The right conveyance drive shaft 72 is connected to the vertical transmission shaft 36a. A vertical conveyance transmission shaft 46 a for driving the vertical conveyance chain 46 is provided. The vertical conveyance transmission shaft 46 a is connected to the vertical transmission shaft 36 a via the right conveyance drive shaft 72. The left stock transfer chain 45L, the left tip transfer tine 47L, the left two-stage star wheel 43L and the drive belt 44L are driven by the rotational driving force branched from the pulling input vertical axis 39a. Further, the rear conveyance drive shaft 76 is connected to the vertical transmission shaft 36a. The auxiliary stock former transport chain 74 and the rear tip transport tine 75 are driven by the rear transport drive shaft 76.

Next, referring to FIG. 6 to FIG. 15, the structure of the headlamp 81 that illuminates the front of the cutting device 3 (running vehicle body 1) and the left and right side covers 82R and 82L that cover the left and right sides of the cutting device 3 will be described. explain. As shown in FIGS. 6 to 8, the left and right sides of the reaping device 3 are provided with left and right side covers 82R and 82L formed of a synthetic resin molded product and left and right light housings 83R and 83L formed of a synthetic resin molded product. Covered by. Left and right light housings 83R and 83L are arranged above the left and right side covers 82R and 82L, respectively. That is, the star wheels 43R, 43L, the take-up belts 44R, 44L, and the stock transport chain 45R, 4
The outer side of 5L, the lower part of the raising case 42, and the like are covered with side covers 82R and 82L. Further, the pulling input lateral case 40 and the upper portion of the pulling case 42 are covered with the light housings 83R and 83L.

  As shown in FIGS. 6 and 10, both end sides of the cover lower support frame 94 are connected to the weeding frame 38 and the pulling support frame 38b. A hook mechanism 95 and a release lever 95a are fixed to the inner surfaces of the left and right side covers 82R and 82L, respectively. The lower end sides of the left and right side covers 82R and 82L are detachably locked to the intermediate portions of the left and right cover lower support frames 94 via hook mechanisms 95, respectively. By operating the release lever 95a, the engagement between the hook mechanism 95 and the cover lower support frame 94 is released, and the lower ends of the side covers 82R and 82L are separated from the cover lower support frame 94.

  As shown in FIGS. 9, 14 and 15, an open / close support 96 is disposed on the upper end side of the left and right side covers 82R, 82L. Further, a cover support frame 87 is connected to the left end portion of the pulling input side case 40 via a lamp support frame 86 described later. An open / close fulcrum shaft body 97 is disposed on the cover support frame 87. An open / close fulcrum shaft 97 having a horizontal axis is extended in the front-rear direction along the upper edges of the side covers 82R and 82L. The side covers 82R and 82L are rotatably connected to the opening / closing fulcrum shaft body 97 via the opening / closing support 96. The upper edges of the side covers 82R and 82L are formed so as to be inclined forward so that the front side is lowered. A horizontal shaft-like opening / closing fulcrum shaft body 97 is supported in a forward inclined posture.

  Further, as shown in FIG. 9, the main body side of the left and right gas springs 101 is rotated through the universal joint shaft 100 between the vertical direction middle of the pulling input vertical case 39 and the vertical middle of the pulling vertical frame 50. Connect to each other movably. The piston sides of the left and right gas springs 101 are rotatably connected to the inner surfaces of the side covers 82R and 82L via the locking shafts 102, respectively. By operating the release lever 95a to disengage the hook mechanism 95 from the lower cover support frame 94, the side covers 82R and 82L are rotated around the opening / closing fulcrum shaft body 97 by the elastic pressure of the gas spring 101. As a result, the lower ends of the side covers 82R and 82L are lifted to a high position on the outer side of the reaping device 3. The lower part of the pulling case 42 installed under the front part of the reaping device 3 and the front part of the cereal conveying device 33 are opened toward the side of the machine body. Maintenance work and the like on the front of the reaping device 3 are performed.

  6 to 8, when the lower side of the side portion of the reaping device 3 is closed by the side covers 82R and 82L, the upper end edges of the side covers 82R and 82L are positioned lower than the pulling input lateral case 40. To position. As shown in FIG. 10, light housings 83R and 83L are arranged above the side covers 82R and 82L. That is, the light housings 83 </ b> R and 83 </ b> L cover the upper side of the side portion of the reaping device 3. Specifically, the left and right outer surfaces of the pulling input side case 40, the openings on the upper ends of the side covers 82R and 82L, and the like are covered with the light housings 83R and 83L.

  As shown in FIGS. 6 to 8, the light housings 83R and 83L are continuously formed along the external shape of the side cover 82 so as not to protrude from the front and side surfaces of the side covers 82R and 82L. Yes. Further, the light housings 83 </ b> R and 83 </ b> L are formed so as not to protrude higher than the upper end of the reaping device 3. That is, the front side and the upper side of the light housings 83R and 83L are formed so as to be substantially flush with the gate cover 105 that covers the front side and the upper side of the pulling input lateral case 40. As shown in FIG. 14, the rear end side of the gate cover 105 is rotatably connected to the pulling input lateral case 40 via an opening / closing shaft 106. The gate cover 105 rotates about the opening / closing shaft 106, and the front end side of the gate cover 105 is configured to open and close up and down.

  As shown in FIGS. 7, 10, 13 to 15, a headlamp 81 and a direction indicator lamp 84 as an auxiliary lamp are arranged inside the light housings 83 </ b> R and 83 </ b> L. The light housings 83R and 83L are entirely formed of a translucent material (polycarbonate resin or the like). The left and right light housings 83R and 83L are formed symmetrically, and the headlamp 81 and the direction indicator 84 inside thereof are also arranged symmetrically. A headlamp 81 is attached so as to illuminate the farm field (traveling road surface) in front of the machine body. A direction indicator lamp 84 is attached so as to be visible from the front and the side. A headlamp 81 is disposed in the upper part of the light housings 83R and 83L. A direction indicator lamp 84 is disposed below the headlamp 81.

  Next, with reference to FIG. 15, the inner structure of the light housings 83R and 83L will be described by exemplifying the left light housing 83L. As shown in FIG. 15, the headlamp 81 is supported by a headlamp reflector 110 (a reflector for the headlamp 81) and a head valve support 111 located at the bottom (back bottom) of the reflector 110. Further, the head lamp 112 (headlight bulb) and a head lens 113 attached to the front portion of the headlight reflector 110 are configured. The headlamp 113 is formed in a substantially round shape when viewed from the front, and the headlamp 81 is arranged so that the headlamp 113 is substantially perpendicular to the ground surface. The upper and front corners of the light housings 83R and 83L facing the upper end of the headlamp 81 are formed in a rounded convex shape so as to cover the headlamp 81.

  As shown in FIG. 15, the direction indicator lamp 84 is supported by a direction indicator reflector 114 (a reflecting mirror for the direction indicator lamp 84) and a direction indicator valve support portion 115 located at the bottom (back bottom) of the direction indicator reflector 114. The direction indication valve 116 and the direction indication lens 117 attached to the front portion of the direction indication reflector 114 are configured. The head bulb support 111 and the direction indicating bulb support 115 are disposed on the lamp support frame 86. A headlamp 81 and a direction indicator lamp 84 are assembled to the upper and lower sides of the light housings 83R and 83L.

  As described above, the headlamp lens 113 is attached to the headlamp reflector 110 and the direction indicator lens 117 is attached to the direction indicator reflector 114, but the light housing 83R corresponding to the irradiation direction of the headlamp 81, The upper front side of 83L can be processed so as to function as the head lens 113. The lower side of the light housings 83R and 83L corresponding to the irradiation direction of the direction indicator lamp 84 can be processed so as to function as the direction indicator lens 117. That is, the light housings 83R and 83L that cover the headlamp 81 and the direction indicator lamp 84 can also be used as the head lens 113 and the direction indicator lens 117.

  Next, with reference to FIG. 6 thru | or FIG. 10, FIG. 12, the structure of the upper surface side cover 120 which covers the upper side of the grain feeder 33 is demonstrated. As shown in FIGS. 6, 7, and 12, a round pipe-shaped cutting upper frame 121 extending in the front-rear direction of the cutting device 3 is provided on the upper side of the grain feeder 33. The rear end side of the upper cutting frame 121 is connected to the cutting input frame 35. The front end side of the upper cutting frame 121 is connected to the pulling input lateral case 40 via the fastening bracket 122. A cutting upper frame 121 is installed in the front-rear direction on the upper side of the grain feeder 33. An upper surface side cover 120 formed of a synthetic resin molded product is detachably connected to the cutting upper frame 121. That is, the upper surface side cover 120 is used as a dustproof cover on the upper surface side of the reaping device 3. The upper side cover 120 covers the upper side of the cereal conveyance device 33 and is configured to prevent dust from being scattered in the direction of the operation unit 10 from the cereal conveyance device 33.

  As shown in FIGS. 6 to 10, the side cover 82 </ b> L is provided with an upper end edge, a rear end edge on the upper surface side of the light housing 83 </ b> L, a rear end edge on the rear surface side, and a rear end edge of the gate cover 105. The front end edge and the lower end edge of the front part are joined to each other so as to be able to contact and separate. That is, the upper side of the side cover 82L, the rear side of the light housing 83L, and the rear side of the gate cover 105 are configured to be shielded by the front portion of the upper surface side cover 120.

  As shown in FIGS. 1 to 4, an auger stand 125 is erected on the upper surface side of the threshing device 5. The discharge auger 8 is supported at the storage position on the upper surface side of the traveling machine body 1 via the auger stand 125. The discharge auger 8 is supported in a substantially horizontal posture by the auger stand 125. As shown in FIG. 3, the discharge auger 8 at the storage position is extended from the right rear corner of the traveling machine body 1 toward the left front corner. A work lamp 126 is disposed on the lower side of the middle of the discharge auger 8. A work lamp 126 is supported on the discharge auger 8 substantially directly above the gate cover 105. The rightmost weed body 38a is irradiated with light from the work lamp 126. The operator can confirm the tip position of the rightmost weed body 38a with respect to the stock of the rightmost uncut grain culm adjacent to the already cut surface of the field during night work.

  As shown in FIGS. 6, 10, 14, etc., the traveling machine body 1 equipped with the engine 20, the reaping device 3 having the culm pulling device 31, the cutting blade device 32, the culm transporting device 33, and the like, and the reaping device 3, a side cover 82R, 82L that covers the side of 3, an upper surface side cover 120 that covers the top of the cutting device, and a light housing 83R, 83L in which the headlamp 81 is installed. The lower end side of the light housing 83R, 83L is connected to the upper end side, the lower side portion of the reaping device 3 is covered with the side covers 82R, 82L, and the upper side portion of the reaping device 3 is covered with the light housings 83R, 83L. ing. Therefore, the side covers 82R and 82L can be formed in a simple shape with little relation to the light housings 83R and 83L. By installing the light housings 83R, 83L at a higher position than the side covers 82R, 82L, the headlamp 81 can be easily arranged at a higher position of the cutting device 3. The front of the reaping device 3 can be effectively illuminated.

  As shown in FIG. 13, FIG. 15, etc., a plurality of pulling case 42 for forming the grain raising device 31, and a pulling input side case as a branching case for pulling input that supports the upper end side of the pulling case 42 40, and light housings 83R and 83L are arranged on the outer side of the pulling input lateral case 40 extended in the left-right direction. Therefore, it is possible to easily assemble the light housings 83R, 83L and the headlamp 81 using the pulling input side case 40.

  As shown in FIGS. 6 to 8, etc., the front end sides of the upper surface side covers 82R and 82L are connected to the rear end sides of the light housings 83R and 83L and the upper end sides of the side covers 82R and 82L. Therefore, the rear end side of the light housing 83R, 83L or the upper end side of the side covers 82R, 82L is shielded by the front end side of the upper surface side cover 82R, 82L, and the rear portion of the light housing 83R, 83L can be easily protected by the upper surface side cover 120. Although it is a thing, the external shape of the cutting device 3 can be formed simply.

  As shown in FIGS. 13, 15, etc., a pulling input vertical case 39 is provided as a pulling input support case standing on the cutting frame 30 of the cutting device 3, and the pulling input horizontal case 40 has an upper end of the pulling input vertical case 39. In this structure, the power is transmitted to the headlamp 81 in the light housing 83R, 83L and the cutting blade device 32 in plan view between the pulling input vertical case 39 and the side covers 82R, 82L. A cutting blade drive shaft 49c is arranged. Therefore, even though the driving mechanism of the cutting blade device 32 such as the cutting blade drive shaft 49c can be arranged away from the grain transporting path, the machine body structure in which the horizontal width dimension of the cutting device 3 is limited, Since the pulling input vertical case 39 can be disposed inward of the mowing device 3, the installation space in the left-right direction of the headlamp 81 can be easily secured between the pulling input vertical case 39 and the side covers 82R and 82L.

  As shown in FIG. 9 and the like, the cutting frame 30 of the cutting device 3 is provided with an opening / closing fulcrum shaft body 97 as a cover rotation fulcrum shaft, the opening / closing fulcrum shaft body 97 is extended in the front-rear direction, and the cutting frame 30 has an opening / closing fulcrum shaft body. The upper ends of the side covers 82R and 82L are connected via 97. Therefore, by rotating the side covers 82R, 82L around the opening / closing fulcrum shaft body 97, the lower ends of the side covers 82R, 82L can be lifted to a high position, and the culm transporting device 33 inside the reaping device 3 can be lifted. The maintenance workability such as can be easily improved.

  Next, with reference to FIG. 16 thru | or FIG. 24, the structure of the corn straw raising apparatus 31 for 4-row cutting is demonstrated. As shown in FIGS. 16 to 18, the pulling input lateral case 40 is divided into three parts on the left side, the center, and the right side. The left end of the left pulling input lateral case 40 is connected to the speed change case 39b via the left pulling drive case 41. The left end of the central pulling input horizontal case 40 is connected to the right end of the left pulling input horizontal case 40 via a central left pulling drive case 41. The right end of the right pulling input horizontal case 40 is connected to the right end of the central pulling input horizontal case 40 via the central right pulling drive case 41. A pulling vertical frame 50 is connected to the right end of the right pulling input horizontal case 40 via a right pulling drive case 41. In other words, four pulling drive case 41 are connected side by side through three divided pulling input horizontal cases 40.

  As shown in FIGS. 16 to 20, one pulling input horizontal shaft 40a is passed through the pulling input horizontal case 40 and the four pulling drive case 41 divided into three sections. A pulling input horizontal shaft 40a is rotatably supported on the pulling input horizontal case 40 via a bearing bearing 131. A pulling input horizontal shaft 40a is connected to the pulling input vertical axis 39a through a set of bevel gear mechanisms 132. Four pulling tine drive shafts 41a are connected to the pulling input horizontal shaft 40a via four sets of bevel gear mechanisms 133. In other words, the pulling tines 42a for the four strips are each driven via the pulling input horizontal shaft 40a. Further, the split input lateral case 40 divided into three is fastened to a fastening bracket 122 welded to the upper cutting frame 121 by a case fixing bolt 134 so as to be detachable.

  As shown in FIG. 19 to FIG. 24, a bearing cylindrical portion 135 is integrally formed at the end portion of the pulling input lateral case 40. Both end openings 136 of the pulling drive case 41 are fitted into the bearing cylindrical portion 135. Both end openings 136 are rotatably fitted to the bearing cylindrical portion 135, and the pulling input horizontal shaft 40 a is passed through the both end opening 136 of the pulling drive case 41. A pulling drive case 41 is connected to the pulling input horizontal case 40 via a bearing cylindrical portion 135 so as to be rotatable around the pulling input horizontal shaft 40a. By causing the pulling drive case 41 to rotate about the pulling input horizontal axis 40a, the pulling case 42 integrally connected to the pulling drive horizontal case 40 is also configured to rotate about the pulling input horizontal axis 40a. .

  As shown in FIG. 19 to FIG. 24, one end side flange 137 is integrally formed on the outer periphery of the bearing cylindrical portion 135 on one end side of the pulling input side case 40. The other end side flange 138 is integrally formed on the outer periphery of the bearing cylindrical portion 135 on the other end side of the pulling input side case 40. One end side flange 139 and the other end side flange 140 are integrally formed in both end opening portions 136 of the pulling drive case 41. When the pulling input lateral case 40 and the pulling drive case 41 are combined via the bearing cylindrical portion 135 and the both end openings 136, the one end side flange 137 of the pulling input side case 40 and the one end side flange of the pulling drive case 41 are combined. 139 contacts. At that time, the other end side flange 138 of the pulling input side case 40 and the other end side flange 140 of the pulling drive case 41 are also in contact with each other.

  As shown in FIGS. 19 to 24, bolt insertion holes 141 are formed in one end side flange 137 of the pulling input side case 40, one end side flange 139 of the pulling drive case 41, and the other end side flange 140 of the pulling drive case 41. Form each one. The case connecting bolt 142 is inserted into each bolt insertion hole 141 from one side of the flange 137 at one end of the pulling input lateral case 40. A screw hole 143 is formed in the flange 138 on the other end side of the pulling input side case 40. When the screw 144 on the front end side of the case connecting bolt 142 is screwed into the screw hole 143, the pulling input lateral case 40 and the pulling drive case 41 are fastened by the case connecting bolt 142, and the pulling case 42 is shown by a solid line in FIG. It is constituted so as to be supported by the work posture in which the cereals shown in FIG.

  As shown in FIGS. 22 and 24, a mounting hole 145 communicating with the bolt insertion hole 141 of the pulling drive case 41 is formed in the flange 137 on one end side of the pulling input lateral case 40. A mounting screw hole 146 communicating with the bolt insertion hole 141 of the pulling drive case 41 is formed in the other end side flange 138 of the pulling input side case 40. The pulling drive case 41 and the pulling case 42 are integrally rotated around the pulling input horizontal axis 40a from the grain raising and pulling work posture shown by the solid line in FIG. 23 to bring the pulling case 42 to the maintenance posture shown by the solid line in FIG. The mounting hole 145 communicates with the bolt insertion hole 141 of the pulling drive case 41 and the mounting screw hole 146 communicates with the bolt insertion hole 141 of the pulling drive case 41 when the lower end side of the pulling drive case 41 is lifted upward. Yes.

  That is, when the lower end side of the pulling case 42 is lifted upward in the maintenance posture shown by the solid line in FIG. 24, the bolt insertion hole 141 of the pulling drive case 41, the mounting hole 145 and the mounting screw hole 146 of the pulling input lateral case 40. In addition, the case connecting bolt 142 is inserted. When the screw 144 on the distal end side of the case connecting bolt 142 is screwed into the mounting screw hole 146, the pulling input lateral case 40 and the pulling drive case 41 are fastened by the case connecting bolt 142, and the maintenance shown by the solid line in FIG. The pulling drive case 41 and the pulling case 42 are configured to be supported in the posture (the non-wrinkle pulling work position).

  Note that when the lower end side of the pulling case 42 is lifted upward in the maintenance posture shown by the solid line in FIG. 24, the case insertion is connected to the bolt insertion hole 141 of the pulling drive case 41 and the mounting hole 145 of the pulling input lateral case 40. Even if the case connection bolt 142 is not fastened to the mounting screw hole 146 in the state where the bolt 142 is inserted, the drive case 41 and the lift drive case 41 are lifted in the maintenance posture (non-wrinkle pulling work position) shown in FIG. Needless to say, the case 42 is supported.

  24, when lifting the lower end side of the elevating case 42 to the maintenance posture shown by the solid line in FIG. 24, the weeding bolt 38c is released and the weeding body 38a is separated from the front end side of the weeding frame 38. Thereafter, the fastening of the case connecting bolt 142 is released, the lower end side of the pulling case 42 is lifted upward, the case connecting bolt 142 is inserted into the mounting hole 145 or the mounting screw hole 146, and the maintenance posture shown by the solid line in FIG. The pulling case 42 is supported. That is, after separating the weed body 38a from the weed frame 38, the fastening of the case connecting bolt 142 is released, the pulling case 42 is rotated around the pulling input horizontal axis 40a, and the upper part of the grain is raised from the position where the grain is raised. The pulling case 42 is configured to move to a work position (maintenance position).

  As shown in FIG. 17 to FIG. 24, a traveling machine body 1 having a traveling unit 2 that is operated by an engine 20, a reaping device 3, and a threshing device 5 are provided. It is configured so as to be raised by the cereal haul raising device 31, to cut the stock source of the cereal husk by the cutting blade device 32, and to transport the cereal husk to the threshing device 5 by the cereal haul conveying device 33, In a combine in which a plurality of pulling cases 42 for multiple strips are provided side by side in the pulling device 31, a pulling drive case 41 as a plurality of gear cases respectively provided on the back side of the plurality of pulling cases 42 for multiple strips, and each pulling drive A plurality of pulling input lateral cases 40 as a plurality of driving input cases that respectively connect the cases 41 are arranged on the upper end side of each pulling case 42, and the plurality of pulling input lateral cases 40 are supported by the cutting upper frame 121 of the cutting device 3. ,each Each pulling drive case 41 is configured to be fastened by the case connecting bolt 142 to the pulling input lateral case 40, and therefore, a plurality of pulling cases 42 and each pulling drive case 41 for multi-row cutting, for example, one line. It can be formed into a unit structure that can be easily disassembled every minute. It is possible to easily reduce the manufacturing cost of the culm pulling apparatus 31 with different numbers of cutting lines and to improve the maintenance workability of the culm pulling apparatus 31 with different numbers of cutting lines. That is, a plurality of pulling case 42 and a plurality of pulling drive cases 41 (a plurality of pulling units) are assembled in a state in which one set of pulling case 42 and pulling drive case 41 is assembled as a single pulling unit. Can be attached. The pulling case 42 and the pulling drive case 41 (the pulling unit) can be shared by the cutting devices 3 having different numbers of cutting lines. It is possible to improve workability in an assembly process of a manufacturing place where a plurality of types of combine is manufactured and maintenance workability such as assembly or disassembly of the pulling case 42 in a maintenance service place that handles a plurality of types of combine.

  As shown in FIGS. 17, 18, and 20, the pulling input horizontal shaft 40 a as a driving shaft is pulled through each pulling input horizontal case 40, and the pulling tine drive shaft as the pulling transmission shaft in the pulling drive case 41 is provided. Since the pulling input horizontal shaft 40a is connected to 41a via the bevel gear mechanism 133, the upper end side of the pulling case 42 can be easily supported on the upper cutting frame 121 via the pulling input horizontal case 40. However, for example, the pull-in input horizontal shaft 40 a having a length corresponding to the number of pull-up lines can be easily assembled via the pull-in input horizontal case 40.

  As shown in FIGS. 20 to 24, a case connecting bolt 142 is passed through one end side flange 137 of the pulling input lateral case 40 and one end side flange 139 of the pulling drive case 41, and the other end side flange 140 of the pulling drive case 41 is passed through. The case connecting bolt 142 is penetrated, and the screw 144 of the case connecting bolt 142 is screwed to the other end side flange 138 of the pulling input side case 40, and the lower end side is directed upward with the upper end side of the pulling case 42 as the center. When rotating, the case connecting bolts are inserted into the mounting holes 145 and the mounting screw holes 146 of the flanges 137 and 138 of the pulling input lateral case 40 via the bolt insertion holes 141 of the flanges 139 and 140 of the pulling drive case 41. 142 is configured to pass through, it is necessary to provide a special member for lifting and supporting the pulling case 42. There. Using the case connecting bolt 142, the pulling case 42 can be easily supported in the upward rotation posture. Loss of the case connection bolt 142 can be prevented in the maintenance work or the like of the cereal conveyance device 33 that is executed while the pulling case 42 is rotated upward. In addition, while the operator lifts the pulling case 42 with one hand, the case connecting bolt 142 can be attached with the other hand to open the front of the grain feeder 33, while the worker pulls with one hand. While supporting the case 42 in the raised position, the case connecting bolt 142 can be removed with the other hand, and the pulling case 42 can be lowered.

  As shown in FIGS. 11, 22 to 24, a plurality of multiple weed frames 38 and a weed body 38 a are provided side by side on the front side of each pulling case 42. The pulling case 42 is configured to be rotatable around the pulling input horizontal shaft 40a in the pulling input horizontal case 40 in a state where the grass body 38a is separated and the case connecting bolt 142 is released. It is possible to move the pulling case 42 from the grain raising position to the upper non-working position without disassembling 42 or the pulling drive case 41. The front side of the cereal conveyance device 33 behind the pulling case 42 can be largely released. Maintenance workability of the cereal conveyance device 33 and the like can be improved.

It is a left view of the combine for 4 thread cutting of this invention. It is a right view of a combine. It is a top view of a combine. It is a front view of a combine. It is a drive system figure of a reaping device. It is a left view of a reaping device. It is a front view of a reaping device. It is a top view of a reaping device. It is opening / closing explanatory drawing of a side cover. It is a left view of the cutting device which removed the side cover. It is a left view of the cutting device which removed the side cover and the light housing. It is a top view of the cutting device which removed the side cover and the light housing. It is a front view of the cutting device which removed the side cover and the light housing. It is a principal part expansion left view of the cutting device which removed the side cover and the light housing. It is a principal part enlarged plan view of the reaping device which removed the side cover and the light housing. It is a front view of a culm pulling device and a culm conveying device. It is a front view of the culm pulling device and the culm conveying device with the pulling case removed. It is an enlarged front view of the upper part of a culm pulling device and a culm conveying device. It is explanatory drawing of the connection part of a pulling input horizontal case and a pulling drive case. It is sectional drawing of the connection part of a pulling input side case and a pulling drive case when a pulling case raises and is supported by the attitude | position. It is sectional drawing of the connection part of a pulling input side case and a pulling drive case when a pulling case raises and is supported by the attitude | position. It is sectional drawing of the connection part of a pulling input side case and a pulling drive case when a pulling case is supported by the raising attitude | position. It is a side view of the connection part of a pulling input side case and a pulling drive case when a pulling case raises and is supported by the attitude | position. It is a side view of the connection part of a pulling input side case and a pulling drive case when a pulling case is supported by the raising posture.

1 traveling body 2 traveling crawler (traveling section)
3 Cutting device 5 Threshing device 20 Engine 31 Grain raising device 32 Cutting blade device 33 Grain conveying device 38 Dividing frame 38a Dividing body 40 Pulling input lateral case (drive input case)
40a pulling input horizontal axis (pulling drive shaft)
41 Pull-up drive case (gear case)
41a pulling tine drive shaft (lifting drive shaft)
42 pulling case 121 mowing upper frame 133 bevel gear mechanism 137 one end side flange 138 pulling input side case 138 other end side flange 139 pulling driving case one end side flange 140 pulling driving case other end side flange 142 case connection Bolt 145 mounting hole

Claims (2)

A traveling machine body having a traveling unit that is operated by an engine, a reaping device, and a threshing device, wherein the reaping device causes the cereal culm planted in a field to be raised by the culm pulling device, and The original is cut with a cutting blade device, and the threshing device is configured to convey the cereal with the cereal conveying device, and a plurality of pulling cases for multiple strips are provided side by side with the culm raising device. In the combine,
A plurality of gear cases respectively provided on the back side of the plurality of pulling cases for multiple stripes and a plurality of drive input cases for connecting the gear cases respectively are arranged on the upper end side of the pulling cases, and reaper is supported a plurality of drive input case upper frame, wherein configured to fastened in each gear case to case connecting bolts to the respective drive input case,
Each drive input case is raised and penetrated through the drive shaft, and the drive shaft is raised and coupled to the drive shaft in the gear case via a bevel gear mechanism.
A case connecting bolt is passed through one end side flange of the drive input case and one end side flange of the gear case, a case connecting bolt is passed through the other end side flange of the gear case, and the other end side flange of the drive input case is The case connecting bolt is configured to be screwed so that the case connecting bolt penetrates the mounting holes of the flanges when the lower end side is turned upward about the upper end side of the pulling case. Composing,
Combine. A structure in which a plurality of multiple weed frames and weed bodies are provided side by side on the front side of each pulling case, each of the weed bodies is separated from each of the weed frames, and the case connecting bolt is fastened. In the released state, the pulling case is configured to be rotatable around the pulling drive shaft in the driving input case.
The combine according to claim 1.

Images