JP2020072768A - Combine-harvester - Google Patents

Abstract

To enlarge a feeder house 11 for increasing a reaping amount of a reaping part 3 and reaping width of a grain header 12.SOLUTION: A combine-harvester of the present invention comprises: a reaping part 3 for reaping and loading unreaped grain culms; a threshing part 9 for threshing reaped grain culms supplied from the reaping part 3; a feeder house 11 for conveying the grain culms reaped by the reaping part 3 and loading them in the threshing part 9; and a driving device 63 that is disposed at one side in a width direction of a machine body of the feeder house 11, changes the speed of motive power of an engine 7 mounted on a travel machine body 1, and transmits it to left/right travel parts 2. The driving device 63 includes hydraulic continuously variable transmission parts 64 and 70 for changing the speed of the motive power of the engine 7. The hydraulic continuously variable transmission parts 64 and 70 are provided at one of left/right side faces opposite to the feeder house 11 in the driving device 63.SELECTED DRAWING: Figure 7

Description

  The present invention relates to a combine equipped with a mowing unit for mowing uncut grain culms in a field and a threshing unit for slashing grains of the mowing grain culm.

  Conventionally, there is a technique of transmitting the output of the engine to the reaper via a vehicle speed synchronized drive mechanism or a vehicle speed non-synchronized drive mechanism (see Patent Documents 1 to 2). Further, a traveling machine body having a traveling section and a driving seat, a mowing section having a cutting blade, a threshing section having a handling cylinder, a feeder house for supplying mowing grain culms from the mowing section to the threshing section, and an engine for driving each section. Also, there is a technique of providing a grain selection mechanism for selecting the grain-removed products of the threshing unit, and continuously cutting uncut grain culms in the field to thresh (see Patent Documents 2 to 4). Furthermore, there is also a technique in which the mowing device is normally rotated to mow the grain culms in the field, and the mowing device is reversed to remove the clogged straw in the feeder house (see Patent Document 4).

Japanese Patent No. 3842176 Utility model registration No. 2563916 JP, 2006-262871, A JP, 2010-239980, A

  In this type of combine, it has been desired to make the feeder house as large as possible in order to increase the amount of cutting at the cutting section and the cutting width of the grain header.

  Therefore, the present invention is intended to provide a combine that has been improved by examining these current situations.

  In order to achieve the above-mentioned object, the present invention provides a mowing unit that captures an uncut grain culm while mowing, a threshing unit that performs a threshing process on the cultivated grain culm supplied from the reaping unit, and the reaping unit cuts the cultivated grain culm. A feeder house that conveys and feeds into the threshing unit, and a drive device that is arranged on one side of the feeder house in the machine width direction and that transmits the power of the engine mounted on the traveling machine body to the left and right traveling units, In the combine, the drive device includes a hydraulic continuously variable transmission unit that shifts the power of the engine, and the hydraulic continuously variable transmission unit is a left and right side of the drive device opposite to the feeder house. It is provided on one side.

  In the combine of the present invention, a steering unit is provided at one side of the front portion of the traveling machine body in a machine body width direction of the drive device, and the hydraulic continuously variable transmission unit includes a straight traveling hydraulic continuously variable transmission and a swing hydraulic system. A linear hydraulic continuously variable transmission and the swing hydraulic continuously variable transmission are arranged side by side on the control section side of the left and right side surfaces of the drive unit. May be.

  In the combine of the present invention, the input shaft that projects from the left and right side surfaces of the drive device is provided with an input pulley that receives the engine power, and the power transmitted to the input shaft is distributed in the drive device, The engine power may be transmitted to the straight traveling hydraulic continuously variable transmission and the swing hydraulic continuously variable transmission via the input shaft.

  In this case, since the power is distributed within the drive device with the input shaft as one axis, the power input mechanism from the engine to the drive device can be made compact and the number of parts in the drive device can be reduced. Since it suffices to wind the engine output belt that transmits the engine power around one input pulley, the drive device can be easily assembled and maintained.

  According to the present invention, since a space is formed on the side of the drive device on the feeder house side, the degree of freedom in designing the cutting unit is increased, and the feeder house is configured with an optimum size for the cutting amount of the cutting unit and the cutting width of the grain header. it can. Further, since the width of the feed house in the left-right direction is widened, the feed house can be installed on the side close to the center of gravity when the grain header is moved up and down, and the support strength of the mowing section by the feeder house can be increased. ..

It is a left side view of the combine showing a 1st embodiment of the present invention. It is a right view of the combine. It is a top view of the combine. It is a perspective view of the threshing part seen from diagonally forward. It is a drive system diagram of a combine. It is a drive system diagram of a mission case. It is the perspective view which looked at the mission case part from the left front. It is the perspective view which looked at the mission case part from the upper part. FIG. 9 is an enlarged explanatory diagram of FIG. 8. It is the perspective view which looked at the mission case part from the right front side. It is a drive system diagram of the combine which shows 2nd Embodiment.

  Embodiments embodying the present invention will be described below with reference to the drawings (FIGS. 1 to 10) applied to a normal combine. 1 is a left side view of the combine, FIG. 2 is a right side view thereof, and FIG. 3 is a plan view thereof. First, a schematic structure of a combine will be described with reference to FIGS. 1 to 3. 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.

  As shown in FIGS. 1 to 3, the ordinary combine in the embodiment includes a traveling machine body 1 supported by a pair of left and right crawler tracks 2 made of a rubber crawler as a traveling portion. At the front part of the traveling machine body 1, a reaping unit 3 for taking up uncut grain culms such as rice (or wheat, soybeans, or corn) while mowing is mounted by a single-acting hydraulic cylinder 4 for raising and lowering. ing.

  A threshing unit 9 for threshing the cut culm supplied from the reaping unit 3 is mounted on the left side of the traveling machine body 1. A grain selection mechanism 10 for performing swing selection and wind selection is arranged below the threshing unit 9. An operator's cab 5 on which an operator rides is mounted on the front right side of the traveling machine body 1. The engine 7 as a power source is arranged in the driver's cab 5 (below the driver's seat 42). Behind the driver's cab 5 (on the right side of the traveling machine body 1), a grain tank 6 for extracting grains from the threshing section 9 and a grain for discharging grains in the grain tank 6 toward a truck carrier (or container, etc.) Arrange the discharge conveyor 8. The grain discharge conveyor 8 is tilted to the outer side of the machine, and the grains in the grain tank 6 are carried out by the grain discharge conveyor 8.

  The mowing unit 3 includes a feeder house 11 that communicates with a handling port 9a at the front of the threshing unit 9, and a horizontally long bucket-shaped grain header 12 that is continuously provided at the front end of the feeder house 11. A scraping auger 13 (platform auger) is rotatably supported in the grain header 12. A take-in reel 14 with a tine bar is arranged above the front part of the take-in auger 13. A clipper-shaped first cutting blade 15 is arranged at the front of the grain header 12. Left and right grass bodies 16 are provided on both left and right sides of the front part of the grain header 12. Further, a supply conveyor 17 is installed inside the feeder house 11. A cutting grain culm charging beater 18 (front rotor) is provided on the feed end side (handle 9a) of the supply conveyor 17. The lower surface of the feeder house 11 and the front end of the traveling machine body 1 are connected via a lifting hydraulic cylinder 4, and the cutting unit 3 moves up and down with a cutting input shaft 89 (feeder house conveyor shaft), which will be described later, as a lifting fulcrum. It moves up and down by the hydraulic cylinder 4 for.

  With the above configuration, the tip end side of the uncut grain culm between the left and right grass bodies 16 is scraped by the scraping reel 14, the culm side of the uncut grain culm is cut by the first cutting blade 15, and the scraped auger is used. By the rotation drive of 13, the cut culms are collected near the entrance of the feeder house 11 near the center of the width of the grain header 12. The whole amount of the cut grain culms of the grain header 12 is conveyed by the supply conveyor 17 and is introduced into the handling port 9a of the threshing unit 9 by the beater 18. In addition, a horizontal control hydraulic cylinder (not shown) for rotating the grain header 12 around a horizontal control fulcrum axis is provided, and the horizontal inclination of the grain header 12 is adjusted by the horizontal control hydraulic cylinder. It is also possible to support 12, the first cutting blade 15, and the take-in reel 14 horizontally with respect to the field scene.

  Further, as shown in FIGS. 1 and 3, a handling barrel 21 is rotatably provided in the handling room of the threshing unit 9. A handling barrel 21 is pivotally supported on a handling barrel shaft 20 extended in the front-rear direction of the traveling machine body 1. On the lower side of the handling cylinder 21, a catching net 24 for letting down the grain is stretched. A spiral screw blade-shaped intake blade 25 is provided on the outer peripheral surface of the front portion of the handling cylinder 21 so as to project radially outward.

  With the above configuration, the harvested culm thrown from the handling port 9a by the beater 18 is conveyed toward the rear of the traveling machine body 1 by the rotation of the handling drum 21, while being transferred between the handling drum 21 and the receiving net 24. Are kneaded and threshed. Grains such as grains smaller than the mesh of the receiving net 24 leak from the receiving net 24. Straws and the like that do not leak from the net 24 are discharged to the field from the dust outlet 23 at the rear of the threshing unit 9 by the conveying action of the handling cylinder 21.

  In addition, a plurality of dust-sending valves (not shown) for adjusting the transfer speed of the grain removal in the handling chamber are pivotally mounted on the upper side of the handling cylinder 21. By adjusting the angle of the dust delivery valve, the transport speed (residence time) of the grain-removed grains in the handling chamber can be adjusted according to the variety and the nature of the cut grain culms. On the other hand, as a grain selection mechanism 10 arranged below the threshing unit 9, a swing sorting disc 26 for specific gravity sorting having a Glen pan, a chaff sieve, a Glen sieve, a Straw rack, etc. is provided.

  In addition, as the grain selection mechanism 10, a blast fan-shaped Kara 29 or the like for supplying the selection wind to the swing selection board 26 is provided. The threshing that has been threshed by the handling cylinder 21 and leaked from the net 24 is carried out by the specific gravity sorting action of the swing sorting disc 26 and the wind sorting action of the blast fan-shaped Kara 29, which causes No.), a mixture of grains and straw (a second product such as a grain with a branch stem), and straw waste, etc.

  As the grain selection mechanism 10, a first conveyor mechanism 30 and a second conveyor mechanism 31 are provided on the lower side of the swing selection board 26. Grain (first product) dropped from the swing sorting disc 26 by the sorting of the swing sorting disc 26 and the blast fan-shaped Kara 29 is collected in the grain tank 6 by the first conveyor mechanism 30 and the lifting grain conveyor 32. It The mixture of grain and straw (second) is returned to the sorting start end side of the swing sorting board 26 via the second conveyor mechanism 31 and the second reduction conveyor 33, and re-sorted by the swing sorting board 26. It Straws and the like are configured to be discharged to the field from the dust outlet 23 at the rear of the traveling machine body 1.

  Further, as shown in FIGS. 1 to 3, the driver's cab 5 is provided with a control column 41 and a driver's seat 42 on which an operator sits. The steering column 41 includes an accelerator lever 40 for adjusting the rotation speed of the engine 5, a round-shaped steering handle 43 for changing the course of the traveling body 1 by an operator's rotation operation, and a main for switching the traveling speed of the traveling body 1. A shift lever 44 and an auxiliary shift lever 45, a harvesting clutch lever 46 that drives or stops the harvesting section 3, and a threshing clutch lever 47 that drives or halts the threshing section 9 are arranged. Further, a sunshade roof body 49 is attached to the front upper surface side of the Glen tank 6 via a sun visor strut 48, and the sunshade roof body 49 covers the upper side of the cab 5.

  As shown in FIGS. 1 and 2, left and right track frames 50 are arranged on the lower surface side of the traveling machine body 1. The track frame 50 includes a drive sprocket 51 that transmits the power of the engine 7 to the crawler belt 2, a tension roller 52 that maintains the tension of the crawler belt 2, and a plurality of track rollers 53 that keeps the ground side of the crawler belt 2 in a grounded state. An intermediate roller 54 that holds the non-grounded side of the crawler belt 2 is provided. The front side of the crawler belt 2 is supported by the drive sprocket 51, the rear side of the crawler belt 2 is supported by the tension roller 52, the ground side of the crawler belt 2 is supported by the track roller 53, and the non-ground side of the crawler belt 2 is supported by the intermediate roller 54. Configure to allow.

  Next, the drive structure of the combine will be described with reference to FIGS. As shown in FIG. 5, the transmission case 63 is provided with a linear hydraulic continuously variable transmission 64 for traveling shifting, which has a hydraulic linear pump 64a and a hydraulic linear motor 64b. The engine 7 is mounted on the right upper surface of the front part of the traveling machine body 1, and the mission case 63 is arranged on the front part of the traveling machine body 1 on the left side of the engine 7. An output shaft 65 protruding leftward from the engine 7 and a mission input shaft 66 protruding leftward from the mission case 63 are connected via an engine output belt 67, an engine output pulley 68, and a mission input pulley 69. There is.

  Further, a steering swing hydraulic continuously variable transmission 70 having a hydraulic swing pump 70a and a hydraulic swing motor 70b is provided in a mission case 63, and a straight hydraulic continuously variable transmission 64 and a swing hydraulic continuously variable transmission are provided via a mission input shaft 66. While the engine 7 output is transmitted to the machine 70, the steering handle 43, the main speed change lever 44, and the auxiliary speed change lever 45 control the output of the linear hydraulic continuously variable transmission 64 and the turning hydraulic continuously variable transmission 70, and the linear hydraulic pressure is not transmitted. The crawler belts 2 on the left and right are driven via the step transmission 64 and the swing hydraulic continuously variable transmission 70 so as to travel and move in a field or the like.

  Further, as shown in FIGS. 4 to 10, a handling cylinder drive case 71 that pivotally supports the front end side of the handling barrel shaft 20 is provided. The handling cylinder drive case 71 is arranged on the front side of the threshing unit 9. A handling cylinder input shaft 72 for driving the reaping unit 3 and the handling barrel 21 is pivotally supported on the handling barrel drive case 71. In addition, the Karasou shaft 76 is provided as a constant rotation shaft that penetrates the threshing unit 9 to the left and right. A working section input pulley 83 is provided on the right end of the Karato shaft 76. The right end of the Karako shaft 76 is connected to the engine output pulley 68 on the output shaft 65 of the engine 7 via a threshing clutch 84 that also serves as a tension roller and a working unit drive belt 85.

  As shown in FIGS. 4 and 5, in front of the handling barrel 21, the handling barrel input shaft 72 extending in the lateral direction of the traveling machine body 1, the beater 18 arranged in the lateral direction of the traveling machine body 1, and the left and right sides of the traveling machine body 1 are provided. A reaping input shaft 89 extending in the direction is provided. As the handling barrel input mechanism 90 for transmitting the driving force of the Karoto shaft 76 to the handling barrel input shaft 72, the handling barrel driving pulleys 86 and 87 and the handling barrel driving belt 88 are provided, and the driving force from the engine 7 is transmitted. The handling cylinder input mechanism 90 (the handling barrel drive pulleys 86, 87 and the handling barrel drive belt 88) is arranged at one end of the engine 7 on the engine 7 side so that the handling barrel 21 is driven to rotate at a constant rotation output of the engine 7. I am configuring.

  Further, as the vehicle speed non-synchronous drive mechanism 100 for constant rotation of the cutting input, which transmits the driving force of the Karako shaft 76 as the constant rotation shaft to the cutting input shaft 89 (beater shaft 82), the cutting drive pulleys 106 and 107 and the cutting drive belt. 114, a constant rotation clutch 108, and a constant rotation switching arm 109, and a vehicle speed non-synchronous drive mechanism at the other end of the Karako shaft 76, which is opposite to the one end on the engine 7 side where the handle barrel input mechanism 90 is arranged. 100 (mowing drive pulleys 106, 107, mowing drive belt 114, constant rotation clutch 108) are arranged, and the mowing unit 3 is driven to rotate at a constant speed by a constant rotation output of the engine 7.

  Further, as shown in FIG. 4, the cutting support frame 36 is installed on the upper surface side of the front part of the threshing machine casing support 34 on the upper surface side of the traveling machine body 1. A mowing bearing body 37 is attached to the front left side of the mowing support frame 36, and a forward / reverse switching case 121 described later is attached to the right side of the front surface of the mowing supporting frame 36, and the mowing bearing body 37 and the forward / reverse switching case 121 are used to cut the mowing A reaping input shaft 89 is rotatably supported on the front side of the support frame 36 so as to be rotatable in the left and right directions of the traveling machine body 1, and inside the reaping support frame 36, a beater shaft 82 is provided in the left and right direction via a beater bearing body 38 ( The beater 18) is pivotally supported. Further, a handling barrel drive case 71 is attached to the upper surface side of the mowing support frame 36, and a handling barrel input shaft 72 is pivotally supported by the handling barrel drive case 71.

  On the other hand, it is provided with a right and left reaping input shaft 89 that drives the supply conveyor 17 in the feeder house 11. The reaping drive force transmitted from the engine 7 to one end of the Karohino shaft 76 on the engine 7 side is transferred from the other end of the Karohino shaft 76 on the opposite side of the engine 7 to the forward / reverse rotation transmission shaft 122 of the cutting normal / reverse rotation switching case 121. To communicate. The cutting input shaft 89 is driven through the forward rotation bevel gear 124 or the reverse rotation bevel gear 125 of the cutting forward / reverse rotation switching case 121. Further, the beater shaft 82 on which the beater 18 is supported is configured to transmit the mowing drive force from the engine 7 to the mowing input shaft 89 via the mowing drive chain 116 and the sprockets 117 and 118.

  That is, as shown in FIGS. 4 to 9, the driving force of the engine 7 is transmitted from the reaping input shaft 89 (beater shaft 82) to the reaper 3, and the left and right sides of the beater shaft 82 opposite to the engine 7 are transmitted. The constant rotational driving force of the engine 7 is transmitted from the other end to the reaping unit 3 via the constant rotation clutch 108.

  Further, as shown in FIG. 4 to FIG. 10, the threshing section 9 is provided with a left-right handling cylinder input shaft 72 on the front side, and the driving force transmitted from the engine 7 to the one end of the Karako shaft 76 on the engine 7 side is input to the handling cylinder input. The shaft 72 is to be transmitted to one end of the shaft 7 on the engine 7 side, the handling barrel input shaft 72 is provided on the front side of the threshing unit 9, the handling barrel input shaft 72 is arranged in the lateral direction of the traveling machine body 1, and is arranged in the front-back direction of the traveling machine body 1. The handling barrel 21 is pivotally supported on the handling barrel shaft 20, and the front end side of the handling barrel shaft 20 is connected to the other left and right ends of the handling barrel input shaft 72 opposite to the engine 7 via the bevel gear mechanism 75. The driving force of the engine 7 is transmitted from the other right and left ends of the Karato shaft 76 on the opposite side to the engine 7 to the grain selecting mechanism 10 for selecting the grains after threshing or the cutting unit 3.

  That is, the right end portion of the handle barrel input shaft 72 is connected to the right end portion of the counter shaft 73 near the engine 7 via the handle barrel drive pulleys 86, 87 and the handle barrel drive belt 88. A front end side of the handling barrel shaft 20 is connected to a left end portion of the handling barrel input shaft 72 extending in the left-right direction via a bevel gear mechanism 75. The power of the engine 7 is transmitted from the right end of the counter shaft 73 to the front end side of the handling barrel shaft 20 via the handling barrel input shaft 72, and the handling barrel 21 is rotationally driven in one direction. On the other hand, the driving force of the engine 7 is transmitted from the left end of the Karato shaft 76, which supports the Kara 29 like a blower fan, to the grain selection mechanism 10 arranged below the threshing unit 9.

  Further, the left end of the first conveyor shaft 77 of the first conveyor mechanism 30 and the left end of the second conveyor shaft 78 of the second conveyor mechanism 31 are connected to the left end of the Karako shaft 76 via the conveyor drive belt 111. The parts are connected. The left end of the second conveyor shaft 78 is connected to the left end of a crank-shaped swing drive shaft 79, which pivotally supports the rear part of the swing sorting board 26, via a swing sorting belt 112. That is, the threshing clutch 84 is turned on / off by the operator's operation of the threshing clutch lever 47. Each part of the grain selection mechanism 10 and the handling cylinder 21 are configured to be driven by the operation of engaging the threshing clutch 84.

  The fried grain conveyor 32 is driven via the first conveyor shaft 77, and the most sorted grains of the first conveyor mechanism 30 are collected in the grain tank 6. In addition, the second reduction conveyor 33 is driven via the second conveyor shaft 78, and the second selection grain (second) in which the straw waste of the second conveyor mechanism 31 is mixed is the upper surface side of the swing selection board 26. Returned to. Further, in the structure in which the dust outlet 23 is provided with a spreader (not shown) for scattering straw, the left end of the Karako shaft 76 is connected to the spreader drive pulley 104 and the spreader drive belt 105.

  As shown in FIG. 5, a cutting input shaft 89 is provided as a conveyor input shaft that pivotally supports the feed end side of the supply conveyor 17. A header drive shaft 91 is rotatably supported on the right side rear surface side of the grain header 12. The left end of the beater shaft 82 was connected to the left end of the mowing input shaft 89 via the mowing drive chain 116 and the sprockets 117 and 118, and was extended in the left-right direction via the header driving chain 119 and the sprocket 120. The left end of the cutting drive shaft 89 is connected to the left end of the header drive shaft 91. A scraping shaft 93 that supports the scraping auger 13 is provided. The intermediate portion of the header drive shaft 91 is connected to the right end of the scraping shaft 93 via a scraping drive chain 92.

  Further, a reel shaft 94 that pivotally supports the take-in reel 14 is provided. An intermediate portion of the header drive shaft 91 is connected to the right end portion of the reel shaft 94 via an intermediate shaft 95 and reel drive chains 96 and 97. The first cutting blade 15 is connected to the right end of the header drive shaft 91 via a first cutting blade drive crank mechanism 98. The supply conveyor 17, the scraping auger 13, the scraping reel 14, and the first cutting blade 15 are drive-controlled by an on / off operation of the constant rotation clutch 108 or a mowing clutch 115 which will be described later, so that the uncut grass culm in the field is removed. The tip side is continuously cut.

  As shown in FIG. 5, a forward rotation bevel gear 124 integrally formed with the forward and reverse rotation transmission shaft 122, a reverse rotation bevel gear 125 rotatably supported on the reaping input shaft 89, and a forward rotation bevel gear 125 attached to the normal rotation bevel gear 124. The intermediate bevel gear 126 to be connected is internally provided in the forward / reverse switching case 121. The intermediate bevel gear 126 is constantly meshed with the forward bevel gear 124 and the reverse bevel gear 125. On the other hand, a slider 127 is slidably supported on the beater shaft 82 by a spline engagement shaft. The forward rotation bevel gear 124 is configured to be releasably engageable with the forward rotation bevel gear 124 via a claw clutch-shaped forward rotation clutch 128, and the slider 127 is engaged with the reverse rotation bevel gear 125 via a claw clutch-shaped reverse rotation clutch 129. It is configured to be detachably engageable.

  Further, the forward / reverse switching shaft 123 for slidingly operating the slider 127 is provided, the forward / reverse switching arm 123 is provided on the forward / reverse switching shaft 123, and the forward / reverse switching arm 130 is operated by operating the forward / reverse switching lever 212 (forward / reverse operating tool). To rotate the forward / reverse switching shaft 123 to bring the forward rotation bevel gear 124 or the reverse rotation bevel gear 125 into contact with or separate from the slider 127, and to rotate the forward rotation bevel gear 124 or the reverse rotation clutch 129 through the forward rotation clutch 128 or the reverse rotation clutch 129. The slider 127 is selectively locked to the bevel gear 125 for use, and the cutting input shaft 89 is connected to the forward / reverse rotation transmission shaft 122 in the forward or reverse direction.

  As shown in FIG. 5, the right end portion of the auger drive shaft 58 is connected to the output shaft 65 of the engine 7 through the tension pulley-shaped auger clutch 56 and the auger drive belt 57. The lateral feed auger 60 front end side of the bottom of the Glen tank 6 is connected to the left end of the auger drive shaft 58 via a bevel gear mechanism 59. A vertical feed auger 62 of the grain discharging conveyor 8 is connected to a rear end side of the horizontal feed auger 60 via a bevel gear mechanism 61. In addition, a grain discharge lever 55 for turning on and off the auger clutch 56 is provided. The grain discharge lever 55 is attached to the front face of the Glen tank 6 on the rear side of the driver's seat 42 so that the operator can operate the grain discharge lever 55 from the driver's seat 42 side.

  As shown in FIGS. 1, 2, and 4, a clipper-shaped second cutting blade 133 having substantially the same length as the clipper-shaped first cutting blade is provided. Further, a left cutting frame 134, a right cutting frame 135, and a central frame 136 are provided as the second cutting cutting blade frame for mounting the second cutting cutting blade 133 on the traveling machine body 1. A second cutting blade base 137 is fixed to the tip ends of the left frame 134, the right frame 135, and the central frame 136 to form a second cutting blade mechanism 132.

  Left and right ground sleds 138 are provided on both ends of the second cutting blade 137. The second cutting blade 133 is reciprocally mounted between the left and right ground sleds 138 of the second cutting blade base 137. On the other hand, the cab frame of the traveling machine body 1 rotatably supports the base end side of the right frame 135 via the right bearing body. Further, the base frame side of the central frame 136 is rotatably supported by the front frame of the traveling machine body 1 via the support frame body 140.

  As shown in FIG. 5, a second cutting blade drive mechanism 171 for transmitting a driving force from the cutting input shaft 89 to the second cutting blade 133 is provided. The second cutting blade drive mechanism 171 includes a second cutting blade drive chain 172 that transmits a driving force to the second cutting blade 133, and an eccentric rotation that is connected to the second cutting input shaft 89 via the second cutting blade drive chain 172. It has a shaft 174 and a second cutting blade drive crank mechanism 175 connected to the eccentric rotation shaft 174.

  The second cutting blade drive crank mechanism 175 includes a swing rotary shaft 178 connected to the eccentric rotary shaft 174, a swing drive arm 179 connected to the swing rotary shaft 178, and a second cutting blade 133 on the swing drive arm 179. It has a push-pull rod 180 for connecting.

  With the above-described configuration, one-way rotation of the eccentric rotation shaft 174 is converted into swing rotation of the swing rotation shaft 178 (reciprocating rotation for normal and reverse rotation within a certain range) to swing the swing drive arm 179. The second cutting blade 133 is reciprocally slid through the push / pull rod 180, and the second cutting blade 133 is used to remove the remaining culm (the root side of the grain culm) of the field immediately after being cut by the first cutting blade 15. It is configured to cut and reduce the height of the stock that remains in the field.

  Further, the transmission frame 181 having the second cutting blade drive chain 172 therein is provided. One end of the transmission frame 181 is detachably fastened to the cutting bearing body 37, and the left frame 134 is rotatably connected to the other end of the transmission frame 181. That is, the left frame 134 is supported by the cutting bearing body 37 via the transmission frame 181. The second cutting blade drive crank mechanism 175 is arranged inside the second cutting blade drive cover 185 that is detachably supported by the left frame 134.

  With the above configuration, the second cutting blade 133 is operated together with the first cutting blade 15 by driving the cutting unit 3 by operating the constant rotation clutch 108 or a cutting clutch 115 described later to operate, and the first cutting blade 15 causes the field to grow. The tip end side of the uncut grain culm is cut, the tip end side of the grain culm is carried into the threshing section 9 from the feeder house 11, and the grains are taken out from the grain selection mechanism 10 to the grain tank 6. On the other hand, the stump (remaining culm) that remains in the trace of the crop culm in the field cut by the first cutting blade 15 is cut to an appropriate height by the second cutting blade 133, and the stump that remains in the field after harvesting work (stock The height of) is made low to a substantially constant height. By reducing the height of the stumps remaining in the field after the harvesting work, the post-processing work (cultivation work, etc.) in the field can be improved.

  Next, a power transmission structure such as the mission case 63 will be described with reference to FIGS. 5 and 6. As shown in FIGS. 5 and 6, a hydraulic case continuously variable transmission 64 for straight traveling (traveling main shift) having a pair of straight traveling pumps 64a and a straight traveling motor 64b in a transmission case 63, a pair of swing pumps 70a and a swing. A turning hydraulic continuously variable transmission 70 having a motor 70b is provided. The transmission input shafts 66 of the transmission case 63 are connected to the respective pump shafts 258 and 259 of the straight-moving pump 64a and the orbiting pump 70a by gears to be driven. An engine output belt 67 is wound around a mission input pulley 69 on the mission input shaft 66. The output of the engine 7 is transmitted to the mission input pulley 69 via the engine output belt 67 to drive the linear pump 64a and the swing pump 70a.

  Further, a PTO shaft 299 is arranged in the mission case 63. The PTO shaft 299 is configured to be constantly driven by the driving force of the straight-moving motor 64b via the straight-moving motor shaft 260 and the main shift output counter shaft 270. In addition, a PTO pulley 219, a vehicle speed tuning pulley 221, and a tension pulley-shaped cutting device are used as the vehicle speed tuning drive mechanism 220 for the cutting tuning rotation for transmitting the driving force of the PTO shaft 299 to the cutting input shaft 89 (beater shaft 82). A clutch 222, a vehicle speed tuning belt 223, and a one-way clutch 224 are provided. One end side of the PTO shaft 299 is projected from the transmission case 63 to the outside on the left side, a PTO pulley 219 is provided on the PTO shaft 299, and the vehicle speed tuning is performed at one end of the beater shaft 82 on the engine 7 side via a one-way clutch 224. A pulley 221 is pivotally supported, and a vehicle speed tuning belt 223 is wound between the PTO pulley 219 and the vehicle speed tuning pulley 221 via a cutting clutch 222.

  With the above-described configuration, the vehicle speed tuning rotational force of the PTO shaft 299 is transmitted to the beater shaft 82 via the one-way clutch 224 while the cutting clutch 222 is operated by the operator operating the cutting clutch lever 47. The beater 18 and each part of the mowing unit 3 are driven at the vehicle speed synchronized speed by the vehicle speed synchronized rotational force of the PTO shaft 299. At this time, when the constant rotation clutch 108 is operated by the operator and the constant rotation force of the Karako shaft 76 is transmitted to the beater shaft 82, the constant rotation force of the Karoh shaft 76 is higher than the vehicle speed tuning rotation force of the PTO shaft 299. In the case of high-speed rotation, the one-way clutch 224 idles like the state in which the mowing clutch 222 is operated to disengage, and the beater 18 and each part of the mowing unit 3 are operated by the constant rotation force of the Karako shaft 76 via the beater shaft 82. It is driven at a constant rotation speed. For example, even when the vehicle speed synchronizing rotation of the PTO shaft 299 becomes lower than a predetermined speed when turning a headland in a field, the beater 18 and each part of the reaper 3 can be driven at a predetermined speed or more by operating the constant rotation clutch 108. It is possible to prevent problems such as the cutting grain culms from clogging the beater 18 or each part of the cutting unit 3. It should be noted that automatic control can be easily performed such that the constant rotation clutch 108 automatically enters and operates when the vehicle speed tuning rotation of the PTO shaft 299 drops below a predetermined value.

  As shown in FIGS. 5 and 6, the driving force output from the output shaft 65 of the engine 7 is transmitted through the engine output belt 67 and the mission input shaft 66 to the pump shaft 258 of the linear pump 64a and the pump shaft of the swing pump 70a. 259, respectively. In the rectilinear hydraulic continuously variable transmission mechanism 53, the hydraulic fluid is appropriately sent from the rectilinear pump 64a toward the rectilinear motor 64b by the power transmitted to the pump shaft 258. Similarly, in the turning hydraulic continuously variable transmission mechanism 54, the hydraulic oil is appropriately sent from the turning pump 70a toward the turning motor 70b by the power transmitted to the pump shaft 259.

  A charge pump 151 for supplying hydraulic oil to the hydraulic pumps 55, 57 and the hydraulic motors 56, 58 is attached to the pump shaft 259. The linearly variable hydraulic continuously variable transmission mechanism 53 adjusts the inclination angle of the rotary swash plate of the straight-line pump 64a in accordance with the amount of operation of the main shift lever 43 and the steering handle 43 arranged on the steering column 41 to make a straight-line drive. By changing the discharge direction and discharge amount of the hydraulic oil to the motor 64b, the rotation direction and the rotation speed of the straight-moving motor shaft 260 protruding from the straight-moving motor 64b are arbitrarily adjusted.

  As shown in FIG. 6, the rotational power of the straight-travel motor shaft 260 is transmitted from the straight-travel transmission gear mechanism 250 to the auxiliary transmission gear mechanism 251. The sub-transmission gear mechanism 251 includes a sub-transmission low speed gear 254, a sub-transmission medium speed gear 255, and a sub-transmission high speed gear 256 which are switched by the sub-transmission shifters 252 and 253. By operating the auxiliary shift lever 45 arranged on the control column 41, the output rotation speed of the straight-moving motor shaft 260 is selectively switched to a three-stage shift stage of low speed, medium speed, or high speed. .. There is a neutral position (a position where the output of the auxiliary shift becomes zero) between the low speed, the medium speed, and the high speed of the auxiliary shift.

  As shown in FIG. 6, a parking brake shaft 265 (auxiliary shift output shaft) provided on the output side of the auxiliary transmission gear mechanism 251 is provided with a drum-type parking brake 266. The rotational power from the sub transmission gear mechanism 251 is transmitted to the left and right differential mechanisms 257 from the sub transmission output gear 267 fixed to the parking brake shaft 265. The left and right differential mechanisms 257 are respectively provided with planetary gear mechanisms 268. Further, a straight traveling pulse generating rotary wheel 292 is provided on the parking brake shaft 265, and a straight traveling vehicle speed sensor (not shown) detects the rotation speed of the straight traveling output (straight traveling vehicle speed = shift output of the auxiliary shift output gear 267). is doing.

  As shown in FIG. 6, each of the left and right planetary gear mechanisms 268 forms one sun gear 271, a plurality of planet gears 272 that mesh with the sun gear 271, a ring gear 273 that meshes with the planet gears 272, and a plurality of planet gears 272 in the same circle. And a carrier 274 rotatably arranged on the circumference. The carriers 274 of the left and right planetary gear mechanisms 268 are arranged to face each other at appropriate intervals on the same axis. A center gear 276 is fixed to a sun gear shaft 275 provided with left and right sun gears 271.

  The left and right ring gears 273 are concentrically arranged on the sun gear shaft 275, with the inner teeth of the inner peripheral surface thereof meshing with the plurality of planet gears 272. Further, the outer teeth of the outer peripheral surface of each of the left and right ring gears 273 are connected to the steering output shaft 285 via intermediate gears 287 and 288 for left and right turning outputs, which will be described later. Each ring gear 273 is rotatably supported by the left and right forced differential output shafts 277 that protrude outward from the outer surface of the carrier 274 in the left and right directions. The left and right forced differential output shafts 277 are connected to the left and right axles 278 via final gears 278a and 278b. Left and right drive sprockets 51 are attached to the left and right axles 278. Therefore, the rotational power transmitted from the sub-transmission gear mechanism 251 to the left and right planetary gear mechanisms 268 is transmitted from the left and right axles 278 to the respective drive sprockets 51 at the same rotational speed in the same direction, and the left and right crawler belts 2 in the same direction. The traveling machine body 1 is moved straight ahead (forward or backward) by being driven at the same number of revolutions.

  The turning hydraulic continuously variable transmission 54 changes and adjusts the tilt angle of the rotary swash plate in the turning pump 70a according to the turning operation amount of the main speed change lever 43 and the steering handle 43 arranged on the steering column 41. By changing the discharge direction and discharge amount of the hydraulic oil to the swing motor 70b, the rotation direction and the rotation speed of the swing motor shaft 261 protruding from the swing motor 70b are arbitrarily adjusted. Further, a turning pulse generating rotary wheel 294 is provided on a steering counter shaft 280, which will be described later, and a turning rotation sensor (turning vehicle speed sensor) (not shown) rotates the steering output of the turning motor 70b (turning vehicle speed). Is configured to detect.

  Further, in the mission case 63, a wet multi-plate turning brake 279 (steering brake) provided on the turning motor shaft 261 (steering input shaft) and a turning motor shaft 261 via a reduction gear 281. The steering counter shaft 280 to be connected, the steering output shaft 285 to be connected to the steering counter shaft 280 via the reduction gear 286, and the left input to be connected to the left ring gear 273 via the reverse rotation gear 284. A gear mechanism 282 and a right input gear mechanism 283 that connects the steering output shaft 285 to the right ring gear 273 are provided. The rotational power of the turning motor shaft 261 is transmitted to the steering counter shaft 280. The rotational power transmitted to the steering counter shaft 280 is transmitted to the left ring gear 273 as the reverse rotational power via the left intermediate gear 287 and the reverse gear 284 on the steering output shaft 285 in the left input gear mechanism 282. On the other hand, the normal rotation power is transmitted to the right ring gear 273 via the right intermediate gear 288 on the steering output shaft 285 of the right input gear mechanism 283.

  When the auxiliary transmission gear mechanism 251 is set to the neutral position, power transmission from the linear motor 64b to the left and right planetary gear mechanisms 268 is blocked. When the auxiliary transmission gear mechanism 251 outputs an auxiliary transmission other than neutral, power is transmitted from the linear motor 64b to the left and right planetary gear mechanisms 268 via the auxiliary transmission low speed gear 254, the auxiliary transmission medium speed gear 255, or the auxiliary transmission high speed gear 256. .. On the other hand, when the output of the swing pump 70a is in the neutral state and the swing brake 279 is in the on state, the power transmission from the swing motor 70b to the left and right planetary gear mechanisms 268 is blocked. When the output of the turning pump 70a is set to a state other than neutral and the turning brake 279 is turned off, the rotational power of the turning motor 70b is transmitted to the left ring gear 273 via the left input gear mechanism 282 and the reverse rotation gear 284. On the other hand, it is transmitted to the right ring gear 273 via the right input gear mechanism 283.

  As a result, when the turning motor 70b rotates in the normal direction (reverse rotation), the left ring gear 273 rotates in the reverse direction (normal rotation) and the right ring gear 273 rotates in the normal direction (reverse rotation) at the same rotation speed in the opposite directions. That is, the shift output from each of the motor shafts 260 and 261 is transmitted to the drive sprockets 51 of the left and right crawler belts 2 via the auxiliary transmission gear mechanism 251 or the differential mechanism 257, respectively, and the traveling speed of the traveling machine body 1 (traveling) The speed) and the direction of travel are determined.

  That is, when the linear motor 64b is driven with the turning motor 70b stopped and the left and right ring gears 273 fixed, the rotational output from the linear motor shaft 260 is transmitted to the left and right sun gears 271 at the same left and right rotational speeds. The left and right crawler belts 2 are driven at the same rotational speed in the same direction via the gear 272 and the carrier 274, and the traveling machine body 1 travels straight.

  On the contrary, when the turning motor 70b is driven in a state where the straight-moving motor 64b is stopped and the left and right sun gears 271 are stationary and fixed, the left ring gear 273 is normally rotated (reverse rotation) by the rotation power from the turning motor shaft 261. The right ring gear 273 rotates in the reverse direction (forward rotation). As a result, one of the drive sprockets 51 of the left and right crawler belts 2 rotates forward and the other rotates backward, so that the traveling vehicle body 1 changes its direction on the spot (spin turn spin turn).

  Further, by driving the left and right sun gears 271 by the straight-ahead motor 64b and driving the left and right ring gears 273 by the turning motor 70b, a speed difference between the left and right crawler belts 2 occurs, and the traveling machine body 1 moves forward or backward while turning to the ground. Turn left or right (U-turn) with a turning radius larger than the radius. The turning radius at this time is determined according to the speed difference between the right and left crawler belts 2. The vehicle 7 turns left or right while the driving force of the engine 7 is always transmitted to the left and right crawler belts 2.

  Next, with reference to FIGS. 1 to 3 and 7 to 10, a driving operation structure such as the steering wheel 43 will be described. As shown in FIGS. 7 to 10, a step frame 311 that constitutes a footrest flat portion for the operator to ride on the cab 5 is provided. A plurality of supporting leg frames 312 are erected on the upper surface side of the traveling machine body 1, and a step frame 311 is installed on the upper end side of the supporting leg frames 312. The step-on / off step 313 is fixed to the side surface of the support leg frame 312 on the right side outer side of the step frame 311, the hydraulic oil tank 315 is arranged on the inner side of the step-on / off step 313, and the traveling machine body below the front end of the step frame 311 A hydraulic valve unit body 314 is attached to the upper surface of the unit 1.

  Further, a steering case 318 having a steering operation shaft 316 and a continuously variable transmission operation shaft 317 is provided. Both ends of the case supporting lateral frame 319 are connected between the left and right supporting leg frames 312 on the lower surface side of the front part of the step frame 311 and the steering case 318 is detachably fastened and fixed to the substantially horizontal case supporting lateral frame 319. A steering case 318 is supported on the hydraulic valve unit body 314 in a multi-stage manner via a case supporting lateral frame 319. The steering operation shaft 316 is provided so as to project upward from the upper surface of the steering case 318, the steering operation shaft 316 is connected to the steering handle 43 via the steering shaft 321, and the left side surface of the steering case 318 is moved to the left side. A continuously variable transmission operating shaft 317 is provided to project toward the main transmission lever 44, and the continuously variable transmission operating shaft 317 is connected to the main transmission lever 44 via the continuously variable transmission operating rod 322.

  In addition, the continuously variable hydraulic continuously variable transmission 64 and the swing hydraulic continuously variable transmission 70 are provided with a continuously variable transmission case 323. The continuously variable transmission case 323 is fixed to the upper right side of the transmission case 63, and the continuously variable and turning continuously variable transmission operation arm bodies 324 are arranged on the front and rear surfaces of the continuously variable transmission case 323. The straight operation shaft 325 and the turning operation shaft 326 provided on the back side of the steering case 318 are connected to the continuously variable and turning continuously variable operation arm bodies 324, respectively, and the steering operation of the steering handle 43 and the main speed change lever 44 are performed. With the gear shifting operation, the linear hydraulic continuously variable transmission 64 and the turning hydraulic continuously variable transmission 70 are operated and controlled so that the path and the moving speed of the left and right crawler belts 2 can be changed.

  In addition, the hydraulic oil tank 315 is arranged on the lower right side of the step frame 311 which is rectangular in a plan view, the continuously variable transmission case 323 is arranged on the lower left side of the step frame 311, and the hydraulic valve unit is arranged below the front part of the step frame 311. Since the body 314 and the steering case 318 are arranged vertically in a multi-stage manner, the front of the engine 7 (the hydraulic oil pump) at the rear of the steering case 318 is forwarded through the space formed between the hydraulic oil tank 315 and the continuously variable transmission case 323. It is possible to easily extend the hydraulic pipe between the hydraulic valve unit body 314, the hydraulic oil tank 315, and the hydraulic actuators (elevating hydraulic cylinders 4) of the respective parts, and improve the maintenance workability of the hydraulic equipment.

  Next, with reference to FIG. 11, a drive structure of the combine (mowing unit 3) according to the second embodiment will be described. As shown in FIG. 11, a pouring gear case 333 having a vehicle speed tuning shaft 331 and a constant rotation shaft 332, and a forward / reverse switching case 121 similar to FIG. 5 are provided. A vehicle speed tuning pulley 221 similar to that shown in FIG. 5 is provided on a vehicle speed tuning shaft 331 via a one-way clutch 224 similar to that shown in FIG. 5, and a vehicle speed tuning belt 223 (vehicle speed tuning drive mechanism 220) is used to tune the vehicle speed to the PTO shaft 299. The shaft speed 331 is connected, and the vehicle speed tuning rotational force of the PTO shaft 299 is input to the pouring gear case 333 via the one-way clutch 224 while the cutting clutch 222 is operated by the operator operating the cutting clutch lever 47. After that, the beater 18 is transmitted to the beater shaft 82, and the beater 18 and each part of the reaper 3 are driven at the vehicle speed synchronizing speed by the vehicle speed synchronizing rotational force of the PTO shaft 299.

  Further, the constant rotation shaft 332 is connected to the output shaft 65 of the engine 7 via the universal joint shaft 334, and a constant rotation clutch (vehicle speed non-synchronized drive mechanism 100) provided in the pouring gear case 333 is turned on and off. The constant rotation switching arm 109, the forward / reverse switching shaft 123 and the forward / reverse switching shaft 123 for selectively connecting the forward rotation bevel gear (not shown) or the reverse bevel gear (not shown) in the forward / reverse switching case 121 to the beater shaft 82. The switching arm 130 is provided, and the beater 18 and each part of the reaper 3 are driven at a constant rotational speed by the constant rotational force of the output shaft 65. That is, similarly to the embodiment shown in FIG. 5, the beater 18 and each part of the reaper 3 are set to either the vehicle speed synchronized speed or the constant rotation speed via either the vehicle speed synchronized drive mechanism 220 or the vehicle speed unsynchronized drive mechanism 100. Driven. The forward rotation bevel gear in the forward / reverse rotation switching case 121 drives the beater 18 and each part of the reaper 3 in the forward rotation to perform the harvesting work, while the forward rotation bevel gear in the forward / reverse switching case 121 causes the beater 18 to move. Each part of the reaping unit 3 is driven in the reverse direction so that the jammed straw can be removed.

  As shown in FIGS. 1 to 5 and 11, the threshing section 9 having the handling barrel 21, the traveling machine body 1 having the engine 7 and the mission case 63 mounted therein, and the mowing section 3 provided in front of the threshing section 9 are provided. In the combine that transmits the driving force from the engine 7 to the threshing unit 9 or the mowing unit 3 and also puts the mowing culm into the threshing unit 9 from the mowing unit 3 through the feeder house 11, from the mission case 63 to the mowing unit 3 The vehicle speed tuning drive mechanism 220 for transmitting the PTO power via the one-way clutch 224 is provided to the threshing drive path for transmitting the power from the engine 7 to the threshing unit 9 via the vehicle speed non-tuned drive mechanism 100. The output of the engine 7 is connected to the supply conveyor 17 of the feeder house 11 via the vehicle speed tuning drive mechanism 220 or the vehicle speed non-synchronization drive mechanism 100 by connecting the cutting input shaft 89 of the cutting unit 3. It is configured to transmit. Therefore, each part of the mowing part 3 such as the supply conveyor 17 of the feeder house 11 is driven at a speed adapted to the amount of mowing culm, power consumption necessary for harvesting work can be reduced, and durability of each part of the mowing part 3 can be improved or Although it is possible to improve the fuel efficiency of the engine 7, it is possible to reduce the occurrence of problems such as straw jam accidents in the feed system path of the cutting conveyor such as the supply conveyor 17 of the feeder house 11 and to reduce the occurrence of harvesting work. It is possible to improve driving operability.

  As shown in FIG. 1 to FIG. 5 and FIG. 11, a vehicle speed tuning drive mechanism 220 or a vehicle speed non-tuning drive mechanism is provided via a power-interrupting reaping clutch 222 that can be operated by an operator at a driving operation unit (driver cab 5). The output of the engine 7 is transmitted from any one of 100 to the supply conveyor 17. Therefore, in association with the headland turning operation or reverse operation in the field during the harvesting work, the output of the vehicle speed tuning drive mechanism 220 or the output of the vehicle speed non-tuned drive mechanism 100 causes each part of the mowing unit 3 to operate at an appropriate speed. It is possible to prevent driving problems from occurring in the transport path of the harvested grain culms in the harvesting section 3, and to improve the driving operability in the harvesting work.

  As shown in FIGS. 1 to 5, the beater 18 as a front rotor is installed between a feed end portion of the supply conveyor 17 and a front portion of the handling cylinder 21 via a beater shaft 82 as a front rotor shaft. The beater shaft 82 is connected to the PTO shaft 299 of the mission case 63 via the one-way clutch 224, and the beater shaft 82 is connected to the Karako shaft 76 as the constant rotation shaft of the threshing unit 9 via the constant rotation clutch 108. There is. Therefore, the mowing unit 3 and the beater 18 can cooperate with each other to insert the mowing grain culm into the handling opening 9a of the threshing unit 9, the transport function of the mowing grain culm can be improved, and the rotation speed of the PTO shaft 299 is equal to that of the Kara shaft 76. Even if the rotation speed is lower than the rotation speed, while the beater shaft 82 is connected to the PTO shaft 299 via the one-way clutch 224, the Karato shaft 76 rotates the beater shaft 82 at high speed via the constant rotation clutch 108. Therefore, it is possible to prevent drive problems from occurring in the cutting culm transport system path in the cutting unit 3, and to improve the driving operability in the harvesting work.

  As shown in FIGS. 1 to 5 and 11, the structure is provided with a forward / reverse switching case 121 as a forward / reverse switching mechanism for driving the supply conveyor 17 in the forward or reverse direction, and the forward / reverse switching case 121 is attached to the beater shaft 82. The supply conveyor 17 is connected via. Therefore, the supply conveyor 17 of the feeder house and the like can be reversed by the reverse rotation switching operation of the forward / reverse switching case 121, and the clogged straw in the feeder house 11 or the like can be quickly removed. Further, the low-speed rotation output of the PTO shaft 299 or the low-speed rotation output of the Karako shaft 76 can be selectively utilized to reverse the supply conveyor 17 of the feeder house 11 and the like, so that the straw jam condition can be adjusted according to the working situation. Can be released.

1 Traveling aircraft 3 Mowing section 5 Cab (driving section)
7 Engine 9 Threshing Section 11 Feeder House 17 Supply Conveyor 18 Beater (Front Rotor)
21 Handling body 63 Mission case 76 Kara axis (constant rotation axis)
82 Beater shaft (front rotor shaft)
89 Mowing input shaft 100 Vehicle speed unsynchronized drive mechanism 108 Constant rotation clutch 121 Forward / reverse switching case (forward / reverse switching mechanism)
220 Vehicle speed tuning drive mechanism 224 One-way clutch 299 PTO shaft

Claims (3)

A reaper that captures uncut culms while harvesting them,
A threshing unit for threshing the cut culm supplied from the reaping unit,
A feeder house in which the mowing unit conveys the mowed culm and puts it in the threshing unit,
A drive device that is arranged on one side of the feeder house in the machine width direction and that transmits the power of the engine mounted on the traveling machine body to the left and right traveling parts,
In a combine with
The drive device includes a hydraulic continuously variable transmission that shifts the power of the engine,
A combine characterized in that the hydraulic continuously variable transmission is provided on one side surface on the opposite side of the feeder device from the feeder house. A steering section is provided on one side of the traveling machine body front side in the machine body width direction of the drive device,
The hydraulic continuously variable transmission is composed of a straight traveling hydraulic continuously variable transmission and a swing hydraulic continuously variable transmission,
2. The combine according to claim 1, wherein the straight-travel hydraulic continuously variable transmission and the swing hydraulic continuously variable transmission are arranged side by side in the front-rear direction on the side of the steering unit on the left and right side surfaces of the drive device. ..   An input pulley that receives the engine power is provided on an input shaft protruding from one of the left and right side surfaces of the drive device, and the power transmitted to the input shaft is distributed in the drive device and is transmitted through the input shaft. The combine according to claim 2, wherein the engine power is transmitted to the straight-travel hydraulic continuously variable transmission and the swing hydraulic continuously variable transmission.

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