JP3977937B2 - General purpose combine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a structure of a Glen tank that stores a first selected item in a general purpose combine.
[0002]
[Prior art]
Conventionally, a general-purpose combiner has a cutting part that is movable up and down in front of the fuselage, a frame is supported on a traveling device behind the cutting part, a sorting device is arranged on the frame, and a screw-type rotor is disposed above the frame. Is placed on the sorting device below the receiving net laid down below the rotor and transported in a spiral shape, the first thing sorted is stored in the Glen tank, and the Glen tank When the tank is full, it can be discharged to a truck bed or the like by a discharge auger arranged so as to be capable of turning and moving up and down above the Glen tank. The Glen tank is arranged on the side of the sorting device and the threshing device, and the Glen tank is formed higher than the combined height of the sorting device and the threshing device arranged above and below, and the continuous volume is increased by increasing the internal volume. It was possible to lengthen the work time.
[0003]
[Problems to be solved by the invention]
However, in order to improve the threshing performance by arranging the rotor of the threshing portion in the left-right direction and extending the threshing path to the left and right so as not to be restricted by the Glen tank, the Glen tank may be arranged above the threshing portion. Although it is conceivable, the height of the glen tank cannot be increased so as to maintain the balance of the entire aircraft, and the internal volume cannot be increased.
[0004]
[Means for Solving the Problems]
The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.
According to claim 1, the sorting device (19) is placed on the traveling device (1), a threshing portion (18) having a left and right rotor is disposed above the sorting device (19), and above the threshing portion (18). In a general-purpose combine having a grain tank (30), the lower part of the grain tank (30) is formed in an inverted triangular funnel shape when viewed from the side, and a horizontal feed conveyor (89) is installed horizontally on the lower part of the funnel shape. The transverse feed conveyor (89) is disposed between the upper portions of the rotors of the threshing section (18) disposed at the front and rear, and an opening is provided below the lateral end of the lateral feed conveyor (89), The opening is below the opening It extends in the front-rear direction and communicates with the discharge conveyor (88) connected to the discharge auger (40), and the Glen tank (30) rotates in the vertical direction around the position of the discharge conveyor (88). It is supported as possible.
In Claim 2, in the general-purpose combine according to Claim 1, the transverse conveyor (89) is driven from the discharge conveyor (88) to the side surface of the Glen tank (30) at the lateral position of the transverse conveyor (89). A drive case (119) is fixed, the drive case (119) is pivotally supported around the screw shaft (88c) of the discharge conveyor (88), and the Glen tank (30) is vertically moved. The drive force of the screw shaft (88c) of the discharge conveyor (88) is taken into the drive case (119) without breaking the power transmission path in the middle even if it is rotated to the drive force to the transverse feed conveyor (89). It is configured to transmit.
In Claim 3, the general purpose combine according to Claim 1 In the sorting device (19) The selected grain is provided so as to be able to be input from the upper part of the left and right sides of the grain tank (30) via the cereal conveyor (29), and the grain is placed immediately before the input part of the cereal conveyor (29). A leveling conveyor (140) extending diagonally from the left and right sides of the upper part of the tank (30) is provided.
According to Claim 4, in the general-purpose combine according to Claim 3, a transmission case (141, 142, 143) for transmitting driving force to the end of the leveling conveyor (140) is provided on a side surface of the Glen tank (30). The input pulley (148) is pivotally supported on the lower part of the transmission case (141, 142, 143), and when the glen tank (30) is rotated downward to the working position, the input pulley ( 148) abuts on the upper surface of the drive belt (154) for transmitting the driving force through the threshing portion (18) and is wound so as to be able to transmit power.
[0005]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below in detail with reference to the drawings. First, the general configuration of a general purpose combine according to the present invention will be described with reference to FIG. FIG. 1 is an overall side view and partial cross-sectional view of a general purpose combine. A machine frame 13 is mounted on the crawler type traveling device 1, and a sorting device 19, a threshing unit 18, and an engine room 49 for storing the engine 48 and the like are mounted and fixed on the machine frame 13. A grain tank 30 is disposed, and a discharge auger 40 for discharging grains stored therein is disposed on the side of the grain tank 30. Further, a cutting portion 8 projects forward from the machine frame 13. The mowing unit 8 houses the lateral feed auger 3 in the platform 2 in the left-right direction, and collects the cereals at substantially the center in the left-right direction by being driven to rotate. A cutting blade 4 is provided horizontally at the lower front end of the platform 2, and a scraping reel 5 is disposed in front of the cutting blade 4. The rear part of the lifting link 6 is pivotally supported on the rear part on both sides of the platform 2, the scraping reel 5 is rotatably supported at the front end of the lifting link 6, and the scraping reel 5 is driven to rotate by a hydraulic motor or the like. The A weeding board 7 is disposed at the front end of each side of the platform 2.
[0006]
A conveying device 9 is disposed between the mowing unit 8 and the threshing unit 18, and the conveying device 9 stores a conveyor 11 in a feeder house 10, and is slightly in the direction of travel from the left and right center of the rear portion of the platform 2. Near the left side, the front end of the feeder house 10 communicates with the feed end position of the screw blade of the lateral feed auger 3. The rear end of the feeder house 10 is communicated with a threshing inlet 12, and a cylindrical beater 34 having a rotation axis in the horizontal direction is arranged in the threshing inlet 12 to force the cereals to a threshing unit. I am going to send it to 18. The rear part of the feeder house 10 is supported by the machine frame 13 so as to be rotatable up and down. Then, a hydraulic cylinder is interposed between the lower surface of the feeder house 10 and the machine frame 13 so that the cutting unit 8 can be moved up and down. Further, a cabin 17 containing a driver's seat 15 and a steering handle 16 is disposed above the feeder house 10 and the beater 34, and the cabin 17 is disposed at an upper position in front of the center of the left and right sides of the fuselage to improve visibility. This makes it easy to check the cutting work.
[0007]
Next, the configuration of the cabin 17, the crawler type traveling device 1, and the engine room 49 will be described. 23 is a plan view of the cabin, FIG. 24 is a side view of the cabin, FIG. 25 is a front view of the cabin, FIG. 26 is a side view of the crawler type traveling device, FIG. 27 is a front sectional view of the idler wheel, and FIG. FIG. 29 is a partial sectional view of a plan view showing a support structure of a tension ring, etc. FIG. 29 is a side sectional view showing an intake structure of an engine room, FIG. 30 is a front sectional view, and FIG.
[0008]
As shown in FIG. 24, the rear part of the cabin 17 is placed on the front part of the machine frame 13 via an anti-vibration rubber 276 so that vibrations from the threshing part 18 and the sorting device 19 are not transmitted. Has been. The cabin 17 can open the front of the beater 34 and the threshing unit 18 by rotating the rear part forward and upward about the left and right pivot point 277 arranged at the front part of the mounting frame 275. These maintenances are made possible.
[0009]
Further, as shown in FIG. 23, boarding steps 256 and 256 project outwardly from the cabin 17 on the left and right sides of the floor 255 below the cabin 17, and stepped in the lower part of the boarding steps 256 and 256. The upper and lower steps 257 and 257 are fixed, and the lower portion of the step 257 is extended to a position just above the farm scene. The operator uses the left and right steps 257 and 257 and the boarding steps 256 and 256. Thus, the passenger can enter and exit from the left and right sides of the cabin 17.
[0010]
As shown in FIGS. 24 and 25, an air conditioner unit 258 is disposed at the rear of the cabin 17, and a condenser 259 for exchanging heat with outside air is disposed below the air conditioner unit 258. Air ducts 260 and 260 bulging inward and downward are formed on the left and right sides of the ceiling portion of the cabin 17, and air outlets 260 a and 260 a are provided at the front of the air ducts 260 and 260 inward and downward, The air whose temperature is adjusted by the air conditioner unit 258 is blown out from the outlets 260a and 260a through the air ducts 260 and 260 to adjust the temperature in the cabin 17.
[0011]
Further, a front column 261 is erected above the left and right central portion of the front portion of the floor 255 of the cabin 17, a steering handle 268 is disposed above the front column 261, and a main transmission lever 262 projects from the upper side surface of the front column 261. ing. A driver seat 263 is provided at the left and right center of the rear portion of the front column 261, and a threshing clutch lever 265 and a reaping clutch lever 266 are disposed on the right side column 264 on the right side of the driver seat 263. An auxiliary transmission lever 269 is provided on the left side column 267 on the left side of the driver seat 263.
[0012]
The sub-transmission lever 269 is pivotally supported at the lower portion thereof by a left and right support shaft so that a sub-transmission operation can be performed in the front-rear direction. Is transmitted to the upper part of the vertical movement link 272 arranged at the rear, and the lower part of the vertical movement link 272 is extended below the cabin 17 to the rear of the traveling mission device 45 arranged at the front part of the machine frame 13 and through the arm 274 The operation is transmitted to the traveling mission device 45. Thus, the sub-shift operation can be performed via the link mechanism, and the operation can be transmitted more accurately than the configuration using the wire.
[0013]
Next, the configuration of the crawler traveling device 1 will be described. Since both the left and right crawler type traveling devices 1 and 1 have the same structure, only the crawler type traveling device 1 on the left side in the traveling direction will be described below.
[0014]
26 to 28, the power from the engine is shifted by a traveling mission device 45 arranged at the front lower part of the fuselage and transmitted to a substantially sprocket-like driving wheel 305 arranged at the front lower part of the machine frame 13. . The crawler type traveling device 1 includes the driving wheel body 305, a track frame 306 connected to the lower part of the machine frame 13, a plurality of idle wheels 307, 307,. The wheel 308 is composed of a rubber crawler belt 309 wound around the driving wheel body 305, the idler wheels 307, 307, and the crawler tension wheel 308, and the power transmitted to the driving wheel body 305. Thus, the crawler belt 309 is driven to rotate.
[0015]
A cored bar 310 is embedded in the crawler belt 309 at an appropriate interval, and the position thereof is arranged at the central portion in the left-right width direction and the substantially central portion in the vertical thickness direction of the crawler belt 309. A hole through which a protrusion on the outer peripheral portion of the sprocket-like driving wheel body 305 can be inserted is provided at the center position in the left-right direction between the core bars 310 in the front-rear direction so that the driving force can be transmitted. Further, the inner claw portions 310a and 310a and the outer claw portions 310b and 310b protrude symmetrically in the inner direction (upward in FIG. 27) from the inner metal portion 310, and the inner claw portions 310a and 310a and the outer The claw portions 310b and 310b are formed in a triangular shape in cross section, and project between the inner claw portion 310a and the inner claw portion 310a with a gap so that the driving wheel body 305 is fitted. In addition, as shown in FIG. 27, the crawler belt 309 is displaced in the left-right direction between the inner claw portion 310a and the outer claw portion 310b as an interval in which the left and right rollers 307a and 307a of the idle wheel 307 are fitted. I'm not guiding you.
[0016]
Three free wheels 307, 307,... Are pivotally supported at the front portion of the track frame 306, and two are pivotally supported at the rear portion of the track frame 306. A sled crawler guide 321 that is long in the front-rear direction is disposed between the left and right rollers of the three idler wheels 307, 307, and 307 on the front side, and the crawler guide 321 is a track between the front and rear idler wheels 307 and 307. It is screwed and fixed to the frame 306, and the left and right central portions of the crawler belt 309 are pressed downward so that the driving force is reliably transmitted from the crawler belt 309 to the field scene. Similarly, a crawler guide 322 is also arranged between the two idler wheels 307 and 307 on the rear side, and the crawler guide 322 is positioned in front of and between the two idler wheels 307 and 307 on the track frame. By screwing and fixing to 306, the attachment span is lengthened to make it difficult for loosening to occur.
[0017]
As shown in FIG. 27, these idler wheels 307, 307... Are pivotally supported by a pivotal portion 333 with a fulcrum pin 307 c of the idler wheel 307 via a bearing or the like, and an upper portion of the pivotal portion 333. A mounting portion 334 is formed so as to protrude upward, and the mounting portion 334 is inserted into a track frame 306 having a “U” shape in a cross-sectional view with its lower portion opened, and is mounted on the same circumference around the fulcrum pin 307c. The mounting member 334 and the track frame 306 are screwed and fixed by the bolts 313, 313, and 313. On the other hand, a plurality of holes 307b, holes 307b,... Are formed on the same circumference as the bolts 313, 313, and 313 on the side surfaces of the left and right rollers 307a and 307a constituting the idler wheel 307.
[0018]
Therefore, the fulcrum pin 307c of the idler wheel 307 can be attached to the track frame 306 in a state where it is pivotally connected by the pivotal portion 333, and the bolt 313 is attached to the track using the hole 307b of the idler wheel 307. It is configured to be inserted into the frame 306 and screwed and fixed, and the fulcrum pin 307c can be assembled to the idler wheel 307 in advance and assembled to the track frame 306, so that the idler wheel 307 can be easily replaced. I can do it.
[0019]
Further, a track frame 306 between the three front idlers 307, 307, and 307 and the two rear idlers 307 and 307, that is, the front and rear central portions of the track frame 306, 26, as shown in FIG. 28, a movable wheel 315 is disposed. That is, a fulcrum pin 318 is horizontally mounted at the front and rear central portions of the track frame 306, and the front upper portions of the support arms 317 and 317 are pivotally supported at the left and right ends of the fulcrum pin 318. A support shaft 315a is pivotally supported at the rear lower portion, and a movable rolling wheel 315 having a narrow left-right width is pivotally supported at the center of the left and right of the support shaft 315a.
[0020]
The movable roller 315 guides the metal core 310a of the crawler belt 309, and even if the crawler belt 309 moves up and down due to the unevenness of the field, the movable wheel 315 moves upward in accordance with the unevenness and the unevenness of the field. In addition to absorbing a large change caused by, the left and right shifts of the Kueru-Labert 309 are prevented.
[0021]
Further, a support frame 324 is provided in a cylindrical holder at the rear upper part of the track frame 306 so as to be slidable in the front-rear direction, and a crawler tension ring 308 is rotatably attached to the rear part of the support frame 324. A receiving body is disposed so that the rear end portion of the tension bolt 325 can come into contact with the front portion of the support frame 324. The receiver includes a plate body 340 that is in contact with the front surface of the support frame 324 and a contact member 341 that is formed of a square member that is screwed to the rear surface of the plate body 340 with a bolt (not shown). The rear portion of the tension bolt 325 is inserted into a hole provided in the upper and lower central portions, and the rear end portion of the tension bolt 325 is brought into contact with the contact member 341. On the other hand, the tension bolt 325 is disposed in the front-rear direction above the rear portion of the track frame 306 and is screwed into a nut portion 326 that protrudes upward from the middle portion of the track frame 306.
[0022]
Accordingly, by tightening the tension bolt 325, the tension bolt 325 is moved back and forth with respect to the nut portion 326, and the position of the support frame 324 is moved via the contact member 341 and the like at the rear end portion of the tension bolt 325. The tension of the crawler belt 309 is adjusted by sliding back and forth. At this time, the pressing force for abutting the front surface of the abutting member 341 at the rear end portion of the tension bolt 325 is transmitted to the plate body 340 via a screw screwed with the abutting member 341, and the crawler belt 309 is configured. Even if an abrupt impact occurs, the impact can be absorbed by the screw that screwed the contact member 341 without being directly transmitted from the crawler tension ring 308 to the tension bolt 325 via the support frame 324. It is. Accordingly, as in the conventional configuration in which an impact is transmitted to the tension bolt 325, the thread of the tension bolt 325 is broken, or the nut portion 326 into which the tension bolt 325 is screwed is damaged. It does not lead to a serious deficit such as replacing everything.
[0023]
As shown in FIG. 28, the rear portion of the support frame 324 that supports the crawler tension ring 308 has an open portion 324a formed in a “U” shape in plan view with the rear open, and the crawler tension ring is formed in the open portion 324a. 308 is attached. That is, the crawler tension ring 308 is a roller having a narrow left and right width, and the support shaft 308a of the crawler tension ring 308 is pivotally supported via the pivotal bodies 331 and 331 that house bearings and the like. The upper portions of the pivotal bodies 331 and 331 are formed in a substantially semicircular shape when viewed from the side, and an attachment edge portion 331a serving as an attachment member is formed. The crawler tension ring 308 is attached by screwing and fixing the mounting edge portion 331a using the mounting bolts 328, 328,... Without interfering with other members from the left and right outer sides of the opening portion 324a. .
[0024]
Thus, when the crawler tension ring 308 is attached to the support frame 324, the support shaft 308a of the crawler tension ring 308 can be attached in advance, and the idler wheels 307, 307,. The assembly property of the crawler type traveling device 1 is improved in combination with the configuration, and the assembly work in the factory and the replacement work in the maintenance become easy.
[0025]
Next, the structure of the intake part to the engine will be described with reference to FIGS. Air for cooling the engine 48 is introduced into the engine room 49 through a rotary screen 280 provided at the upper part of the engine room 49. An introduction port 49a is opened above the engine room 49 above the radiator 281 on the right side of the engine 48, and a suction cover 282 is placed so as to cover the introduction port 49a. The suction cover 282 is formed in a cylindrical shape with the lower part opened, and a gap is provided in part between the upper part of the engine room 49 and the lower part of the suction cover 282, and the outside air is guided into the suction cover 282. A cylindrical rotary screen 280 is disposed in the suction cover 282. The rotary screen 280 has an outer diameter larger than the outer peripheral portion of the introduction port 49a, and the circumferential portion is formed of a dust-proof mesh net.
[0026]
In addition, an annular brush 291 is fixed on the outer periphery of the rotary screen 280 on the engine room 49 on the outer periphery of the introduction port 49a, and covers between the lower part of the rotary screen 280 and the upper part of the engine room 49. Thus, dust or the like does not directly enter the inlet 49a.
[0027]
Further, a suction part 286 of a suction fan 285 for cleaning is disposed in the rear part of the suction cover 282 behind the rotary screen 280. The drive of the suction fan 285 is transmitted from the drive shaft of the radiator fan 292 disposed on the left side of the radiator 281 to the fan drive pulley 293 fixed to the end of the fan shaft 285a of the suction fan 285 via the pulley 291 and the belt 294. Has been. With this driving, the suction fan 285 is rotated so that dust or the like adhering to the mesh screen of the rotary screen 280 is sucked from the suction portion 286.
[0028]
A rotary shaft 283 is disposed at the center of the rotary screen 280 formed in a cylindrical shape, and the arms 288, 288, and 288 are moved from the front and rear middle portions of the rotary shaft 283 toward the upper circumferential surface of the rotary screen 280. The upper part of the rotary screen 280 circumferential surface is fixedly provided at the end. Further, the upper end portion of the rotating shaft 283 is pivotally supported on the upper portion of the suction cover 282 immediately above the rotary screen 280, and the lower portion of the rotating shaft 283 is inserted into a reduction gear case 287 placed on the upper portion of the radiator 281. An electric motor 284 is fixed to the upper part of the reduction gear case 287. The output shaft of the electric motor 284 is inserted into the reduction gear case 287, and the rotation shaft 283 is driven via the gears 289 and 290. The rotary screen 280 is rotated by driving 283.
[0029]
Therefore, even if the engine 48 is continuously driven in an environment where dust such as sawdust flies in the air for harvesting work, the suction air from the radiator fan 292 contains a lot of dust or the like due to the suction force of the radiator fan 292. However, when guided to the left side of the radiator 281 in the engine room 49 through the rotary screen 280 through the rotary screen 280, the dust adheres to the mesh screen of the rotary screen 280, and the dust enters the engine room 49. So that it won't be. Therefore, dust does not adhere to the radiator 281 and the lubricating oil condenser 295 for driving the mission device for traveling and clogging, and the cooling efficiency can be improved.
[0030]
When the rotary screen 280 is rotated, the dust or the like adhering to the mesh screen is sucked and discharged downward from the cleaning suction fan 285. Then, it is dropped onto a later-described spreader 62 at the rear of the sorting device 19 and discharged together with the waste. Therefore, since the rotary screen 280 is automatically cleaned, there is no need to interrupt the work for cleaning the rotary screen 280 and perform maintenance, thereby improving workability.
[0031]
Next, the configuration of the cutting unit 8 will be described. FIG. 13 is a left side view in the traveling direction of the cutting unit, FIG. 32 is a right side view of the cutting unit, FIG. 33 is a partial front view of the cutting unit, FIG. 34 is a partial development view of the cutting unit, and FIG. 36 is a partial rear view of the platform connection configuration, FIG. 37 is a partial side sectional view, FIG. 38 is a partial bottom view of the platform lower connection configuration, and FIG. 39 is the platform upper portion. It is a fragmentary top view of the connection structure of.
[0032]
As described above, the platform 2 of the cutting unit 8 is connected to the front portion of the feeder house 10 which is the transport device 9. The feeder house 10, the beater 34 and the threshing inlet 12 are provided slightly to the left of the left and right center part in the traveling direction of the machine body, and the threshing inlet 12 is disposed at the left front part of the first rotor (front rotor) 21. Thus, the cereals are conveyed to the right by the rotation of the first rotor 21 of the threshing unit 18.
[0033]
Further, the driving force of the lateral feed auger 3, the cutting blade 4 and the take-up reel 5 of the cutting unit 8 is taken out from the front part of the conveyor 11 of the feeder house 10. As shown in FIG. 34, drive sprockets 200 and 200 are fixed to the left and right ends of the conveyance drive input shaft 201 on both the left and right sides in the rear part of the feeder house 10. A pulley 339 is fixed to the end of the conveyance drive input shaft 201, and a driving force from the engine 48 is transmitted through a threshing portion drive transmission path described later. A driven roller 202 is fixed on a driven shaft 203 in the front portion of the feeder house 10, and the driven shaft 203 is pivotally supported on the left and right side surfaces of the front portion of the feeder house 10. Chains 205 and 205 are wound around the left and right end portions of the outer peripheral surface of the driven roller 202 and the outer peripheral surfaces of the drive sprockets 200 and 200, and a plurality of scraper plates 204. The left and right ends of 204... Are fixed to form the conveyor 11.
[0034]
Further, as shown in FIGS. 32 to 34, a transmission shaft 221 is pivotally supported on the right side surface of the front portion of the feeder house 10, and a sprocket 229 is fixed on the transmission shaft 221, and the right end portion of the transport drive input shaft 201 A chain is wound around the sprocket 248 to transmit the driving force to the transmission shaft 221 using the right side surface of the feeder house 10 as a drive transmission path to the cutting portion.
[0035]
On the other hand, a power branch case 207 is disposed on the right side of the rear surface of the platform 2, and a front and rear center portion of a cutting transmission shaft 208 having an axial center on the left and right is horizontally mounted on the power branch case 207. The left end portion of 208 and the right end portion of the transmission shaft 221 are interlocked and connected via a universal joint shaft 206, and are rotated so as to correct the right and left inclination of the cutting portion 8 as will be described later. The driving force is transmitted to the cutting transmission shaft 208 even if the axial position is displaced from the transmission shaft 221. The right end portion of the cutting transmission shaft 208 is extended from the power branch case 207 to the right side platform 2 right side, and a cutting pulley 209 is fixed to the end portion.
[0036]
Further, a driven pulley 222 is fixedly mounted on the auger drive shaft 211 of the lateral feed auger 3 supported on the right side surface of the platform 2 in front of the cutting pulley 209, and the cutting transmission shaft is connected to the cutting pulley 209 via the belt 223. The drive 208 is transmitted to the lateral feed auger 3.
[0037]
A cutting blade drive case 213 is fixed to the front side of the right side of the platform 2, and power is supplied to a pulley 214 pivotally supported by the cutting blade drive case 213 through a belt 215 from another pulley 210 on the auger drive shaft 211. The driving force is transmitted to the cutting blade drive case 213 and the driving blade of the cutting blade 4 is reciprocated in the left-right direction via the link mechanism to cut the stock of the cereal.
[0038]
Further, a reel drive transmission shaft 217 is pivotally supported in the power branch case 207 in parallel with the cutting transmission shaft 208, and power is branched from the cutting transmission shaft 208 in the power branch case 207 to drive the reel drive transmission shaft 217. The The right end portion of the reel drive transmission shaft 217 protrudes to the right side from the right side surface of the platform 2, and the end portion is inserted into the lower portion of the rotation drive case 218. The lower part of the rotational drive case 218 is pivotally supported by the reel drive transmission shaft 217, and the interlocking pivotal shaft 219 is pivotally supported by the upper part of the rotational drive case 218. The reel drive transmission shaft 217 via a pulley and a belt (not shown). Thus, the driving force is transmitted to the interlocking pivot shaft 219. The rear portion of the reel drive case 220 is pivotally connected to the upper portion of the rotation drive case 218, and the drive shaft of the right end portion of the take-up reel 5 is pivotally supported by the front portion of the reel drive case 220. The driving force is transmitted to the take-up reel 5 via a pulley and a belt.
[0039]
A guide groove 220a that is substantially vertically long is opened in the front and rear middle portion of the left side surface of the reel drive case 220, and a support shaft 249a of a tension pulley 249 that supports a belt that transmits drive to the take-up reel 5 is formed in the guide groove 220a. The support position can be adjusted up and down along the belt, and the belt tension can be adjusted without removing the reel drive case 220.
[0040]
Further, the upper part of the rotational drive case 218 is pivotally supported so as to be pivotable back and forth, and is pivotally connected to the side part of the rotational drive case 218. It is supported so that it can rotate up and down. Similarly, as shown in FIG. 13, a rotating arm 225 is pivotally connected to the upper left side of the rear surface of the platform 2 at a position facing the rotating drive case 218, and is opposed to the reel driving case 220 above the rotating arm 225. The swing arm 226 is pivotally supported at a position where the swing reel 226 is pivoted, the pivot shaft on the left side of the take-up reel 5 is pivotally supported at the front end of the swing arm 226, and the left and right ends of the take-up reel 5 are supported. Further, the pivot position of the reel drive case 220 on the upper side of the rotational drive case 218 on the right side of the platform 2 and the pivot position of the swing arm 226 on the upper side of the pivot arm 225 on the left side of the platform 2 are connected via a reinforcing pipe 216. It has increased rigidity.
[0041]
Further, hydraulically driven lifting cylinders 227 and 227 are interposed between the reel driving case 220 and the swing arm 226 and the front and rear middle portions of the left and right sides of the platform 2, respectively. Further, a front / rear adjustment drive cylinder 224 is interposed between the left side portion of the rear surface of the platform 2 and the middle portion of the rotating arm 225.
[0042]
Therefore, the front and rear position of the take-up reel 5 can be adjusted by rotating the rotation arm 225 and the upper portion of the rotation drive case 218 back and forth with respect to the platform 2 by the expansion and contraction drive of the front and rear adjustment drive cylinder 224. It can be done. Then, by extending and retracting the lifting cylinders 227 and 227, the scraping reel 5 can be moved up and down to an appropriate position. The stock of the culm is cut by the cutting blade 4 and conveyed to the center side of the platform 2 by the lateral feed auger 3 to send the cereal to the feeder house 10.
[0043]
Next, the structure which supports the said platform 2 in the feeder house 10 front part is demonstrated. As shown in FIGS. 35 to 39, an upper reinforcing frame 231 is fixed to the upper part of the rear surface of the platform 2 over the lateral width of the platform 2, and a lower reinforcing frame 232 is fixed to the front surface of the lower part of the rear surface of the platform 2. The rigidity of 2 is enhanced. Further, a communication port 2a communicating with the feeder house 10 is opened at the left and right central portions of the rear surface of the platform 2, and a fixing plate 250 is formed above the communication port 2a from the front surface of the rear portion of the platform 2 to the rear surface of the upper reinforcing frame 231. It is fixed. A rotation fulcrum shaft 230 is fixed to the fixed plate 250 above the left and right central portions of the communication port 2a perpendicular to the rear surface of the feeder house 10. The rear portion of the pivot fulcrum shaft 230 is pivotally supported by being inserted into a pivoting pipe 251 fixed to the middle of the left and right of the connecting frame 228 extending to the left and right. The right end of the connection frame 228 extends to the right end of the connection port 2a, and the left end of the connection frame 228 extends further to the left than the left end of the connection port 2a. In addition, fixing plates 241 and 241 are fixed to the front and lower sides of the connection frame 228 at the left and right side positions above the left and right ends of the upper portion of the communication port 2a in accordance with the left and right width of the feeder house 10.
[0044]
Further, a horizontal rotation actuator 233 that is an electric hydraulic pump driven hydraulic cylinder is interposed between the left end portion of the connection frame 228 and the lower rear surface of the feeder house 10. The connecting frame 228 is extended to the left and a horizontal rotation actuator 233 is interposed. This is because a pivot fulcrum shaft 230 that serves as a pivot for the platform 2 is provided at the center of the left and right of the connection port 2a. The connection port 2a is opened slightly to the left of the center of the platform 2 in the left and right direction. Is provided with a drive transmission path to the cutting blade 4, the lateral feed auger 3, etc., and since the center of gravity of the left and right of the cutting part 8 is biased to the right side from the rotation fulcrum shaft 230, a horizontal rotation actuator 233 is provided on the left side. Thus, the right and left balance of the cutting unit 8 is maintained.
[0045]
Further, the horizontal rotation actuator 233 is of an electric hydraulic pump drive type and has a configuration in which a hydraulic pump is driven by an electric motor to drive a cylinder, and is connected to the machine body side by electric wiring. Therefore, for example, it is not necessary to extend the hydraulic piping or the like from the machine body side as compared with the case where the horizontal rotation actuator 233 is a hydraulic cylinder. Therefore, when removing the platform 2 of the cutting unit 8 from the feeder house 10. It can be performed simply by removing the connecting portion (coupler) provided in the middle of the electrical wiring, and the connecting operation is easy.
[0046]
Further, fixed pipes 234 and 234 protrude rearwardly on the rear surface of the platform 2 on the left and right sides below the connection port 2a, and the rear surface of the platform 2 on the upper right side of the right fixed pipe 234 and the upper left side of the fixed pipe 234 on the left side. Fixed pipes 235 and 235 are provided behind the rear surface of the platform 2. The left and right ends of the guide plate 236 are detachably screwed to the rear portions of the two right fixed pipes 234 and 235 using bolts 237 and 237, and the guide plates are fixed to the rear portions of the two left fixed pipes 234 and 235. The left and right ends of 236 are fixed using bolts. The left and right guide plates 236 and 236 are arranged in a reverse “C” shape in the rear view symmetrically about the center line in the vertical direction including the rotation fulcrum shaft 230 (left and right center line of the feeder house 10). Between this guide plate 236 and the rear surface of the platform 2 is a receiving portion, and a guide roller 238 as an engaging portion fixed to the feeder house 10 described later is rotatably engaged.
[0047]
Furthermore, as shown in FIGS. 36 and 38, a stay 242 protrudes from the rear surface of the left guide plate 236, and a damper 245 is interposed between the stay 242 and the middle part on the left side of the connection frame 228 to connect the stay 242. The rotation of the frame 228 around the rotation fulcrum shaft 230 is buffered.
[0048]
Further, a sensing arm 246 protrudes rearward and downward from the lower left side of the platform 2 as shown in FIG. The sensing arm 246 is brought into contact with the farm scene. When the distance between the farm scene and the lower left side of the platform 2 changes, the angle of the sensing arm 246 changes, and the angle is detected by a sensor (not shown) and passed through the controller. The horizontal rotation actuator 233 is controlled to extend and contract. For example, when the sensing arm 246 is rotated upward from a certain range in the rearward and downward direction, it is determined that the lower surface on the left side of the platform 2 has moved away from the farm scene, and the horizontal rotation actuator 233 is driven to contract. When it is rotated downward from a predetermined range in the rear downward direction, the horizontal rotation actuator 233 is driven to extend. However, an absolute angle can be detected without using the sensing arm 246.
[0049]
On the other hand, as shown in FIGS. 35 and 36, a plate-like introduction portion 239 is formed at the front end portion of the feeder house 10. An introduction port 239a smaller than the communication port 2a is opened in the introduction portion 239, and an upper edge portion of the introduction portion 239 is bent rearward along the upper surface of the feeder house 10 to form a fitting portion 239b. The fitting portion 239b is fitted between the connecting frame 228 and the rear surface of the platform 2 so that the platform 2 is fitted.
[0050]
Further, support shafts 240 and 240 protrude from the lower portions of the left and right side surfaces of the front portion of the feeder house 10, and guide rollers 238 and 238 as engaging portions are pivotally supported below the support shafts 240 and 240. Yes. Further, a bracket 244 is fixed to the lower surface of the front portion of the feeder house 10, and a drive cylinder 338 for raising and lowering the cutting portion 8 is connected as shown in FIG. The plate-like member fixed at the lower rear portion of the feeder house 10 is a guide plate 243 formed of rubber or resin for guiding the cereal to the rear beater 34. Further, the engaging portion for engaging the front lower portion of the feeder house 10 and the lower portion of the platform 2 so as to be rotatable around the rotation fulcrum shaft 230 is not limited to the guide roller 238 pivotally supported on the end portion of the support shaft 240. Alternatively, it may be constituted by a bar-like member, and the number of engaging portions is not limited to the number, and a plurality of engaging portions may be provided.
[0051]
Therefore, in order to connect the cutting part 8 to the front part of the feeder house 10, the drive cylinder is extended and retracted to move the feeder house 10 up and down, and the feeder house is connected to the communication port 2a portion of the platform 2 of the cutting part 8 on the ground. 10 Advance the aircraft so that the front part abuts. Then, when the introduction portion 239 is disposed at the position of the communication port 2a and the feeder house 10 is raised, the fitting portion 239b is fitted between the connection frame 228 and the rear surface of the platform 2, and the left and right ends of the fitting portion 239b are fixed. The platform 2 is connected between the plates 241 and 241 so as to be rotatable about the rotation fulcrum shaft 230. Therefore, when connecting the platform 2 and the feeder house 10, it is not necessary to pivotally turn the pivot fulcrum shaft 230. Therefore, the connecting work is facilitated and the working time is shortened. .
[0052]
Further, since the guide plate 236 is removed from the fixed pipes 234 and 235 during the connecting operation, the guide roller 238 is disposed between the fixed pipes 234 and 235, and then the guide plate 236 is attached to the fixed pipes 234 and 235. By screwing, the front lower part of the feeder house 10 and the rear lower part of the platform 2 are supported and guided so as to be firmly connected in a simple structure.
[0053]
As described above, the connecting frame 228 for attaching the feeder house 10 and the horizontal rotation actuator 233 are provided on the platform 2 side, and the guide rollers 238 and 238 are provided on the feeder house 10 side, which is fixed on the machine body side. The feeder house 10 has a simple configuration, and maintenance of the internal conveyor 11 is facilitated.
[0054]
Then, as described above, during the harvesting operation, the horizontal rotation actuator 233 is controlled to expand and contract using the sensing arm 246, and the cutting unit 8 is maintained parallel to the field scene regardless of the inclination of the machine body. At this time, since the damper 245 is interposed between the connecting frame 228 rotatably connected to the feeder house 10 side and the platform 2 of the cutting unit 8, the support load of the horizontal rotation actuator 233 is reduced. Yes. Further, the driving of the cutting unit 8 is configured to be taken in from the feeder house 10, but is transmitted from the transmission shaft 221 at the front part of the feeder house 10 via the universal joint shaft 206, and the platform 2 of the cutting unit 8 is Even if it is rotated so as to be tilted left and right with respect to the feeder house 10, the driving force can be accurately transmitted.
[0055]
Further, the lateral width of the communication port 2a on the platform 2 side is larger than the introduction port 239a of the feeder house 10, and even if the platform 2 is rotated, the left and right sides of the introduction port 239a are not blocked. Can be smoothly introduced into the feeder house 10.
[0056]
Next, the configuration of the threshing unit 8 will be described. 2 is a side sectional view of the threshing unit and the sorting device, FIG. 3 is a plan sectional view of the threshing unit, FIG. 4 is a side sectional view of the threshing unit, FIG. 5 is a side sectional view, and FIG. 7 is a side sectional view showing a maintenance configuration of the beater, FIG. 7 is a sectional plan view of another configuration of the second rotor for discharging the waste from the threshing section, FIG. 8 is a sectional side view of the cereal conveyor, and FIG. FIG. 10 is a front view partially sectional view of a rotational configuration of a threshing portion opening / closing cover that covers the right end of the rotor, FIG. 11 is a right side view in the direction of travel, and FIG. FIG. 14 is a front view showing the pulley position of the engine that transmits power, FIG. 15 is a side view showing the power transmission path to the threshing unit and the traveling device, and FIG. 40 is a side view showing a power transmission path to the sorting device, and FIG. It is a front view showing a formation.
[0057]
The beater 34 is housed in the front upper part of the machine frame 13. As shown in FIG. 6, an outlet 64 for taking out the beater 34 is opened on the left side surface of the machine frame 13, and a shaft support plate 65 is screwed with a bolt or the like so as to cover the outlet 64. A rotating shaft of the beater 34 is pivotally supported at the front and rear central portions of the support plate 65. By removing the bolt with which the shaft support plate 65 is screwed and removing the shaft support plate 65 from the machine frame 13, the beater 34 can be extracted from the outlet 64 and maintenance can be performed.
[0058]
In addition, a cleaning port 66a for maintenance is opened in the middle of the inclined plate 66 on the lower surface of the threshing inlet 12, and a lid 67 is provided so that the cleaning port 66a can be opened and closed. That is, one piece of a hinge 68 is fixed to the rear portion of the cleaning port 66a, the other piece of the hinge 68 is fixed to the lower surface of the rear upper portion of the lid body 67, and the lid body 67 is lowered downward with the left and right fulcrum of the hinge 68 as a center. Is rotated. An edge portion 67a is formed in the front lower portion of the lid body 67 so as to project forward and downward along the lower surface of the lid body 67. When the cleaning port 66a is closed by the lid body 67, the edge portion 67a is immediately below the cleaning port 66a. The cleaning port 66 a is covered with the lid 67 by abutting the lower surface of the inclined plate 66 and screwing the edge 67 a to the inclined plate 66 using the bolt 69. When performing maintenance, the bolt 68 is removed using the opening 70 on the left side of the machine frame 13 below the inclined plate 66, the lid 67 is rotated downward to open the cleaning port 66a, and the beater 34 maintenance is performed.
[0059]
As shown in FIGS. 1 to 3, the threshing portion 18 is composed of a first rotor (front rotor) 21, a second rotor (rear rotor) 22, receiving nets 23 and 24, etc. It is stored. The first rotor 21 and the second rotor 22 are configured in substantially the same shape, and are configured in a screw shape in which screw blades 21a and 22a are provided on the outer periphery of the cylinder. It is arranged in front and back in parallel. In the threshing part in which the rotor having the axial core in the front-rear direction is arranged, the threshing part becomes longer in the front-rear direction, but in the threshing part 18 provided with the rotors 21 and 22 having the axial core on the left and right, it can be shortened in the front-rear direction. The engine room 49 can be provided by using the space above the rear part, and the layout can be performed efficiently.
[0060]
Receiving nets 23 and 24 are disposed below the first rotor 21 and the second rotor 22, respectively, and upper covers 35 and 36 are disposed above the first rotor 21 and the second rotor 22, respectively. And a rear rotor chamber. A seal member 39 made of rubber or resin is interposed between the upper covers 35 and 36 and the machine frame 13 for sealing.
[0061]
Further, as shown in FIG. 9, the upper part of the machine frame 13 (upper machine frame 13 a) has a shape projecting to the right from the lower part of the machine frame 13 (lower machine frame 13 b) that houses the sorting device 19. The first rotor 21 and the second rotor 22 are accommodated in the upper machine frame 13a, and the rotating shafts 21d and 22d of both the rotors 21 and 22 are pivotally supported by a threshing cover. That is, the threshing portion is configured to be longer to the right than the sorting device 19, and the protruding portion serves as a communication portion between the first rotor chamber and the second rotor chamber. In addition, a power transmission unit 110 including a belt and a pulley that transmits power from the engine 48 to the first rotor 21 and the second rotor 22 is disposed on the left side surface of the upper machine frame 13a. Further, as shown in FIGS. 10 to 11, a side frame 77 is fixed on the upper machine frame 13 a to cover the right side surface of the first rotor 21, and hinges 78 and 78 are attached to the upper end of the side frame 77. The right ends of the upper covers 35 and 36 are pivotally supported via hinges 78 'and 78', and are supported so as to rotate upward in accordance with the upward rotation of the Glen tank 30, as will be described later. .
[0062]
As shown in FIGS. 10 to 12, the lower side and the left side of the upper machine frame 13 a below the right side and the right side of the first rotor 21 and the second rotor 22, the front and the first side of the right side of the first rotor 21. A threshing portion opening / closing cover 94 having a substantially square shape in front view and side view is provided on the rear side of the right side of the two rotors 22 so as to cover the front and rear surfaces, the right side surface, and the lower surface of the first rotor 21 and the right side portion of the second rotor 22. I am doing so. Further, the upper part of the threshing part opening / closing cover 94 is formed up and down halfway up the left side surface (threshing cover) of the upper machine frame 13a, and the rotating shaft 21d of the first rotor 21 and the second rotor 22 above the threshing part opening / closing cover 94. · Recesses 94a and 94b are provided around 22d, and pivot plates 13c and 13d are formed on the upper machine frame 13a as a part for pivotally supporting the rotating shafts 21d and 22d. Even if the cover 13 is provided with the opening 13e, the rigidity to pivotally support the rotating shafts 21d and 22d of the first rotor 21 and the second rotor 22 is maintained.
[0063]
Further, one piece of hinges 95 and 95 is fixed to the upper part of the right side surface of the lower machine frame 13b directly below the inner end portion below the threshing portion opening / closing cover 94, and the other pieces of the hinges 95 and 95 are threshed. The upper part of the threshing part opening / closing cover 94 is pivoted downward in the direction around the pivoting fulcrum of the hinges 95, 95. Furthermore, a damper 96 comprising a gas spring is interposed between the lower part of the machine frame 13 and the lower part of the threshing part opening / closing cover 94 so as to assist without requiring a large force when the threshing part opening / closing cover 94 rotates, Moreover, sudden rotation is prevented.
[0064]
Further, pivot brackets 97 and 97 are provided at the center of the upper and lower sides of the threshing portion opening / closing cover 94 so as to protrude in two places in the front and rear and two places in the center. A lock operating shaft 98 extending in the direction is pivotally supported. The end portion of the lock operating shaft 98 extends further forward and rearward than the front and rear end portions of the threshing portion opening / closing cover 94, and hooks 99 and 99 are fixed to the respective end portions. Engagement recesses 103 and 103 are fixedly provided in the upper machine frame 13a inward from the hooks 99 and 99, and the hooks 99 and 99 are moved into the engagement recesses 103 and 103 by rotating the lock operation shaft 98. It is configured to be engaged and locked in.
[0065]
Further, a bracket 100 is fixedly provided at the front and rear central portion of the lock operation shaft 98, and a rod-shaped operation arm 101 is pivotally supported by providing a rotation fulcrum in the circumferential direction of the axis of the lock operation shaft 98. An L-shaped storage guide plate 102 is fixed to the side surface of the threshing portion opening / closing cover 94 below the operation arm 101, and the operation arm 101 is centered on the lock operation shaft 98 when the operation arm 101 is disposed in the storage guide plate 102. Rotation is restricted.
[0066]
Therefore, after the operation arm 101 is rotated forward from the storage guide plate 102 as indicated by a two-dot chain line in FIG. 11, when the operation arm 101 is pulled forward, the lock operation shaft 98 is rotated, and the hooks at both ends are hooked. 99 and 99 come out of the engaging recesses 103 and 103, the lock is released, and the threshing portion opening / closing cover 94 is rotated downward on the side, so that the right ends of the receiving nets 23 and 24 are opened as shown in FIG. Then, the fixing bolts 104, 104,... Can be removed and the receiving nets 23, 24 can be taken out for maintenance or replacement. After receiving the work, the receiving nets 23 and 24 are stored, the threshing portion opening / closing cover 94 is closed, the operation arm 101 is rotated, and the hooks 99 and 99 are engaged in the engaging recesses 103 and 103 to open and close the threshing portion. The cover 94 closes the opening 13e of the upper machine frame 13a.
[0067]
With this configuration, even if it is difficult to perform maintenance below the first rotor 21 and the second rotor 22, the receiving nets 23 and 24 can be connected to the first rotor 21 and the second rotor 22. A part of the right side that is not placed can be opened and taken out, maintenance can be performed quickly, workability is improved, and the receiving nets 23 and 24 can be easily replaced according to the type. As a result, the threshing configuration is tailored to the variety to be harvested, and versatility is improved.
[0068]
Further, a rotor cleaning lid 35a is provided on a part of the front surface of the upper cover 35 having a substantially "U" shape in a side perspective view covering the upper side of the first rotor 21 so as to be opened and closed. As shown in FIG. 6, the lower part of the rotor cleaning lid 35 a is fixed to the front lower part of the upper cover 35 so as to be rotatable by a hinge 73, and a hook 74 projects upward from the upper part of the rotor cleaning lid 35 a to The engagement body 75 can be engaged. Accordingly, the hook 74 is disengaged by the disengagement operation of the engagement body 75, and the upper part of the rotor cleaning lid 35a is rotated forward about the rotation fulcrum of the hinge 73 in the left-right direction. The upper part is opened to perform internal maintenance. A cleaning lid may also be provided on the rear surface of the second rotor 22 to perform internal maintenance from the rear upper part of the second rotor 22.
[0069]
As shown in FIGS. 2 to 4, the rear part on the right side of the receiving net 23 below the first rotor 21 is inclined in a gentle arc shape to the front, rear, and rear height, and in the tangential direction of the upper and outer circumferences of the second rotor 22. The communication portion 23 a is formed by extending toward the front, and the rear end of the communication portion 23 a extends to the vicinity of the front end portion of the rotation locus of the second rotor 22. Further, as shown in FIGS. 2 and 5, a discharge port 24 a is opened at the left rear portion of the receiving net 24.
[0070]
Further, the upper covers 35 and 36 of the first rotor 21 and the second rotor 22 are formed in a substantially “U” shape with the lower part opened in a side view, and as shown in FIG. The right side of the upper cover 36 has a front portion extending in an arc shape from the upper end surface of the second rotor 22 toward the rotating shaft 21d of the first rotor 21 to form a communication upper portion 36a, and the front end of the communication upper portion 36a is the first rotor. 21 extends to the vicinity of the rear end of the rotation locus. And together with the said communication part 23a, the communication port which both threshing spaces of the 1st rotor 21 and the 2nd rotor 22 communicate is formed, and opening of this communication port is enlarged. Further, the front and rear distances between the first rotor 21 and the second rotor 22 are arranged as close as possible to shorten the communication port, and the inoperable space between the first rotor 21 and the second rotor 22 is reduced. To improve inheritance performance.
[0071]
Further, as shown in FIG. 5, the rear portion on the left side of the upper cover 36 of the second rotor 22 is extended so as to be separated rearward and upward from the outer peripheral surface of the second rotor 22, and the discharge upper port 36 b is inclined gently. And an opening for discharging the waste together with the discharge port 24a is enlarged. The communication upper part 36a and the discharge upper part 36b of the upper cover 36 are configured so as to gradually change from a substantially U shape to an arc shape.
[0072]
Further, a guide plate having a substantially triangular shape in a side view toward the outer peripheral surface of the first rotor 21 on the rear side of the inner peripheral surface of the upper cover 35 of the first rotor 21 (upstream side in the rotation direction of the first rotor 21 described later). 37 is fixed. Similarly, a substantially triangular guide in side view toward the outer peripheral surface of the second rotor 21 on the front side of the inner peripheral surface of the upper cover 36 of the second rotor 22 (upstream side in the rotation direction of the second rotor 22 described later). A plate 38 is fixedly installed, and the shedding of cereals conveyed by the first rotor 21 and the second rotor 22 is reversed to promote degranulation.
[0073]
Further, dust feeding valves 59, 59... Are provided at appropriate intervals in the left-right width direction on the inner peripheral surface of the upper part of the upper cover 35, 36 formed in a substantially “U” shape. The upper covers 35 and 36 are pivotally supported so as to be pivotable around a pivot point in the vertical direction. The dust feed valves 59, 59... On the upper cover 35 side and the dust feed valves 59, 59... On the upper cover 36 side are individually rotated, and the cereals move in the first rotor 21. And the time for moving in the second rotor 22 can be adjusted according to the variety of cereals and the state of the cereal, and a versatile threshing unit 18 adapted to various varieties and the like is configured. It is done.
[0074]
The screw blades 21a of the first rotor 21 are formed between the left end of the first rotor 21 and the left side of the communication portion 23a. The outer surface of the first rotor 21 in front of the communication portion 23a Plate-shaped feed blades 21b, 21b,... Projecting in the radial direction are formed. The number of the feed blades 21b, 21b... Is not limited, but three are formed in order to reduce the weight, reduce the number of parts, and increase the conveyance efficiency. Similarly, the screw blade 21a of the second rotor 22 is formed between the right end portion of the second rotor 22 and the right side of the discharge port 24a, and the second rotor ahead of the discharge port 24a on the left side from the terminal portion of the screw blade 22a. 22 are formed on the outer peripheral surface, and the waste after threshing (waste) is sent by the feed blades 22b, 22b, and discharged from the discharge port 24a.
[0075]
Further, as shown in FIG. 3, a drum 21c (drum 22c) on which screw blades 21a (screw blades 22a) and feed blades 21b (feed blades 22b) of the first rotor 21 (and second rotor 22) are fixed. Is formed in a cylindrical shape, and winding preventing plates 58 and 58 are disposed in the left and right ends of the drum 21c (drum 22c). As shown in FIG. 3, anti-winding plates 58 and 58 are fixed to the side of the inner peripheral surface of the machine frame 13 at the position of the first rotor 21 (and the second rotor 22). The anti-winding plate 58 is formed in a disc shape having a hole 58a into which the drive shaft of the first rotor 21 can be inserted at the center and having an outer diameter substantially equal to the inner diameter of the drum 21c. Further, the outer periphery of the anti-winding plate 58 is bent inward to form the edge 58b, and the edge 58b is inserted along the inner peripheral surface of the end of the drum 21c with a slight gap. Thus, the gap between the inner peripheral surface of the machine frame 13 is eliminated so that the cereals are not entangled with the drive shaft of the first rotor 21 (and the second rotor 22).
[0076]
The edge 58b of the anti-winding plate 58 does not have a shape that covers the outer peripheral surface of the end of the drum 21c, and the end of the screw blade 21a extends to the end of the drum 21c by being inserted along the inner peripheral surface. The cereals conveyed to the end of the first rotor 21 (and the second rotor 22) can be sent in the left-right direction by the screw blades 21a, and on the first rotor 21 (and the second rotor 22) The cereal is not retained.
[0077]
Further, the first rotor 21 and the second rotor 22 have the same diameter, and the feed blades 21b, 21b,... And the feed blades 22b, 22b,. The rotation direction of the first rotor 21 is counterclockwise as viewed from the left side of the traveling direction shown in FIG. 2, and the rotation direction of the second rotor 22 is counterclockwise, so that the screw blades 21a and 22a The winding direction can also be made the same, and the first rotor 21 and the second rotor 22 can be made completely the same in shape to increase versatility, thereby reducing costs. Moreover, by making the rotation direction of the second rotor 22 clockwise, the cereals conveyed rearward and upward at the end of the first rotor 21 can be inherited by the second rotor 22 with the conveyance direction being substantially the same direction, It is easy to inherit.
[0078]
Further, the second rotor 22 and the receiving net 24 and the upper cover 36 covering the second rotor 22 are arranged lower than the first rotor 21, the receiving net 23 and the upper cover 35, and a communication upper part 36a. The connection at the communication port formed by the communication part 23a is smooth and improves the threshing performance, and the upper cover 36 is lowered, so that the volume of the Glen tank 30 disposed above can be increased. it can.
[0079]
In such a configuration, when the harvested sorghum is fed from the feeder house 10 to the threshing inlet 12, the harvested sorghum is shed while being conveyed to the right by the rotation of the first rotor 21. And when it reaches the right end of the first rotor 21, it is sent to the threshing space of the second rotor 22 from the communication port formed by the communication part 23a and the communication upper part 36a formed in a gently inclined shape. At this time, the grain rotor is lifted rearward and upward by the first rotor 21 that rotates counterclockwise as viewed from the left side, and is sent to the threshing space of the second rotor 22 through the communication port. Since the height position of the second rotor 22 is lower than the first rotor 21, it can be fed to the front upper part of the second rotor 22, and since the rotation direction of the second rotor 22 is clockwise, The inheritance performance is good.
[0080]
The particles are crushed while being conveyed leftward by the rotation of the second rotor 22. Further, the cereals are bundled and conveyed in a spiral by the screw blades 21a and 22a of the first rotor 21 and the second rotor 22, but the bundle of cereals hits the guide plates 37 and 38 to form a spiral shape. The direction of conveyance can be changed, or the screw blades 21a and 22a can be squeezed and inverted to facilitate the threshing of the bundle-shaped cereals. The grain is reliably dropped on the first half of the sorting device 19. Then, when the remaining waste is sent to the left end of the second rotor 22, it is dropped from the discharge port 24a.
[0081]
In addition, the guide plate 60 extends rearward and downward from the lower portion of the discharge port 24a so that the waste dropped at the discharge port 24a is not dropped to the rear portion of the sorting device 19.
[0082]
That is, as shown in FIGS. 2 and 3, the guide plate 60 extends to a middle position of the rear portion of the sorting device 19, and is forcedly placed between the upper portion of the rear portion of the guide plate 60 and the bottom of the engine room 49. An evacuation beater 61 is provided to send evacuation backward. The rejection beater 61 has a compact and easy-to-assemble shape with an outer diameter smaller than the outer diameter of the rotors 21 and 22, and the rotational speed of the rejection beater 61 is made faster than the rotation speed of the second rotor 22 to eliminate the waste. The peripheral speed of the beater 61 is set to be equal to or higher than that of the rotors 21 and 22 to enhance the performance of sending waste to the rear.
[0083]
Further, the rejecting beater 61 is a cylindrical body having left and right pivots, and has a plurality of reverse V-shaped feed dogs 61a, 61a,. In addition, the left end portion of the discharge beater 61 coincides with the left end portion of the discharge port 24a, the right end portion of the discharge beater 61 extends further to the right side from the right end portion of the discharge port 24a, and the discharge beater discharged from the discharge port 24a. The kite is transported widely left and right, and is inherited by a chipper type spreader 62 that is horizontally mounted on the rear end of the machine, and is cut by a plurality of bowl-shaped blades of the spreader 62. It is discharged from the end to the field. The rejecting beater 61 forms feed teeth 61a, 61a... That are reverse V-viewed from the side, but forms a triangular plate as viewed from the side or is simply a plate-like feed that is long in the left-right direction. Similarly, a configuration provided with blades can also be fed backward.
[0084]
In addition, as shown in FIG. 7, the feed blades 22b ′, 22b ′... Fixed on the left side of the second rotor 22 are fixed in an inclined manner so that the right side is the rear side in the rotational direction from the left side. It is possible to direct the waste discharged backward by the blades 22b ′, 22b ′,... To the center side from the discharge port 24a, and fly the waste toward the right side of the spreader 62 via the waste beater 61. It is possible to improve the diffusibility by the 稈 beater 61, and it is possible to discharge the air widely from the rear end of the machine body by effectively using the entire width of the spreader 62. In addition, by forming the feed dog of the waste beater 61 in an inclined shape, it is possible to fly the waste toward the right side of the spreader 62 to further improve the diffusibility by the waste beater 61.
[0085]
Further, the guide plate 60 is formed into a fence shape using a linear plate body that is long in the front-rear direction and the left-right direction, or formed as a crimping net to be a degranulation processing guide that is shed and dropped downward. It is also possible to further improve the threshing accuracy by feeding back by the straw beater 61 and at the same time loosening the waste and dropping the grain remaining inside on the sorting device 19.
[0086]
Thus, the waste dropped from the discharge port 24a is forcibly sent backward by the waste beater 61 so that the waste is not dropped onto the sorting device 19. The sorting performance is not reduced.
[0087]
The drive shaft 61 b of the rejecting beater 61 is pivotally supported on the left and right side surfaces of the lower part of the machine frame 13 that covers the left and right sides of the sorting device 19, and the drive shaft 61 b protruding rightward from the rejecting beater 61 is provided. It is covered with the cylinder 71 so that the waste or swarf is entangled to prevent drive loss.
[0088]
Further, as shown in FIG. 2, a sorting device (swinging sorting device) 19 is disposed below the threshing portion 18, and the configuration thereof is a drifting grain plate 25, a swinging body 50, and a tang 27 that generates sorting wind. The first conveyor 28 for conveying the sorted first object in the left-right direction, the second conveyor 31 for conveying the second object, and the like. The first conveyor 28 and the second conveyor 31 are laterally arranged behind the crawler type traveling device 1 in a side view, and are connected to the left end portion of the first conveyor 28 and arranged in a vertical manner. The efficient layout is such that the reduction conveyor 32 and the crawler traveling device 1 that are continuously provided at the left end of the leftmost conveyor 28 do not interfere with each other. Further, as shown in FIG. 1, the sorting device 19 is housed between the front and rear middle portions of the machine frame 14 and the rear portion thereof, and is used for traveling driving to the front portion of the machine frame 14 in front of the sorting device 19 and the rear lower position of the feeder house 10. The mission apparatus 45 can be arranged, and the overall length can be shortened as an efficient layout.
[0089]
The swinging main body 50 is arranged from below the front end of the first rotor 21 to the rear end of the sorting device 19, and is swingably supported by a swing link mechanism 51. A grain pan 50a is formed at the front of the swinging body 50 to receive the cereals that have fallen under the first rotor 21 and the second rotor 22. The grain pan 50a is formed in a wave shape in a side view and is conveyed rearward by the swinging of the swinging main body 50. A fluid line 52 is arranged so as to be connected to the rear end of the grain pan 50a. A chaff portion made up of a plurality of chaff fins horizontally arranged in the width direction of the swinging main body 50 is arranged from below the fluid line 52 to the rear end portion of the swinging main body 50. The chaff part includes a movable chaff 53 in which the front-falling inclination angle of the chaff fin changes according to the amount of grain shed from the front side, a manual chaff 54 in which the front-falling inclination angle of the chaff fin is manually changed, and a front-falling inclination angle of the chaff fin Is formed of a fixed chaff 55 to which is fixed. The bottom surface of the swinging main body 50 below the chaff portion is provided with a drop opening 55b and is covered with a crimp net (not shown).
[0090]
Further, a tang 27 is horizontally provided under the front and rear middle part of the grain pan 50a of the swinging main body 50, and the sorting wind is sent rearward according to the guide to blow the sorting wind into the swinging main body 50 from the dropping port 55b or the like. In the chaff part, specific gravity sorting and wind sorting are performed to sort into the first and second items.
[0091]
Constructed in this way, grains, swarf and the like dropped from the receiving nets 23, 24 of the first rotor 21 and the second rotor 22 are received on the grain pan 50a of the swinging main body 50 and conveyed backward. is doing. Then, the grain pan 50a jumps backward from the rear portion of the fluid line 52 or is dropped to the chaff portion as it is to perform the specific gravity selection and wind selection. Since the flow does not fall, the flow on the chaff part performing the sorting becomes smooth and the sorting performance is improved, and even if a large amount of cereal is shed at once, the sorting device 19 reliably processes it. It can be done. Then, the second product is dropped from the second conveyor 31 through the reduction conveyor 32 onto the middle part of the front and rear of the grain pan 50a of the swinging main body 50 so as to be sorted again. It falls onto the first conveyor 28 and is conveyed upward by the cereal conveyor 29 and stored in the glen tank 30.
[0092]
Next, the whipping conveyor 29 will be described. As shown in FIGS. 8 and 9, a cereal conveyor 29 is erected upward from the side of the first conveyor 28 and the second conveyor 31, and extends to the upper part of the left side of the Glen tank 30. Yes. An arc-shaped receiving portion 29a is formed at the lower part of the cereal conveyor 29, and the left end of the conveyor 28 is in communication with the front portion of the receiving portion 29a. A whipping drive sprocket 80 having left and right drive shafts is pivotally supported at the rear position of the first conveyor 28 below the cereal conveyor 29, and a driven sprocket 81 having pivot shafts on the left and right is pivotally supported above the cereal conveyor 29. A chain (or belt) 83 in which buckets 82, 82... Are fixed at appropriate intervals is wound around the drive sprocket 80 and the driven sprocket 81. The casing around the driven sprocket 81 at the top of the cereal conveyor 29 is divided at a position directly below the driven sprocket 81 to form a chute portion 85 extending to the upper surface of the left side portion of the grain tank 30. The tank 30 is in communication.
[0093]
Then, when the cereal drive sprocket 80 is driven, the buckets 82, 82,... Are formed in a cup shape from the first conveyor 28 to the lower part of the cereal conveyor 29 and accumulated in the receiving portion 29a. The pump 82 is pumped up at the position where the sprocket 81 is moved upward and the direction is changed at the position of the driven sprocket 81, and the grain in the bucket 82 is sent to the front chute 85 by the centrifugal force, and the grain is stored in the Glen tank 30. It is done. Further, since the first object is not bitten between the bucket 82 and the casing of the cereal conveyor 29 during conveyance by the bucket 82, it is not damaged like a screw type conveyor.
[0094]
Further, the chute 85 is fixed to the grain tank 30 side, and even if the grain tank 30 is rotated as will be described later, only the chute 85 is rotated off the cereal conveyor 29 side, There is no need to disconnect the conveyor 29 and the Glen tank 30 from each other. In addition, a seal member 352 such as a sponge is fixed to the upper part of the casing on which the chain 83 to which the buckets 82, 82,... The lower rear portion of the chute portion 85 is placed via the seal member 352 when the shape is formed, so that the sealing performance of the cereal conveyor 29 is improved and the conveyed grain does not leak.
[0095]
Next, the power transmission configuration in the threshing unit 18 will be described. As shown in FIGS. 14 and 15, the engine 48 is mounted above the rear part of the machine frame 13, the output shaft of the engine 48 protrudes to the left side, and the drive pulley 160 is located on the left side from the left side part of the machine frame 13. It is fixed. A gear case 161 is fixed to the machine frame 13 on the left side of the rotating shaft 22d of the second rotor 22. A pulley shaft 162a is pivotally supported on the gear case 161, and a second rotor input pulley is mounted on the pulley shaft 162a. 162 and a small-diameter transmission pulley 166 are fixed. Further, the left end portion of the rotating shaft 21d of the first rotor 21 protrudes to the left side from the machine frame 13, and the first rotor input pulley 163 and the transmission pulley 168 are fixed to the end portions. A beater transmission pulley 164 is fixed to the left end portion of the rotation shaft 34 a of the beater 34.
[0096]
A belt 165 is wound between the drive pulley 160 and the second rotor transmission pulley 162, and a belt 169 is wound between the transmission pulley 166 and the first rotor input pulley 163, so that the transmission pulley 168 and the beater transmission pulley are wound. A threshing drive transmission path is configured by winding the belt 170 between the second rotor 22, the first rotor 21, and the beater 34.
Further, the pulley shaft 162a and the rotating shaft 22d are interlocked by a gear (not shown) in the gear case 161 to transmit reverse rotation to the rotating shaft 22d, and the second rotor 22 is transferred to the first rotor 21 as described above. On the other hand, it is rotating backward.
[0097]
The transmission pulley 166 is a double-type pulley, and a belt 178 is wound around the waste beater input pulley 177 at the left end of the drive shaft 61b of the waste beater 61, and the first rotor 21 and the second pulley The rejection beater 61 is driven in conjunction with the two rotors 22.
[0098]
A driven pulley 171 is pivotally supported below the machine frame 13 in the middle of the front and rear, a travel transmission shaft 172 is pivotally supported at the lower front of the machine frame 13, and a travel input pulley 174 is disposed at the left end of the travel transmission shaft 172. It is fixedly connected to the transmission device 45 from the right end of the travel transmission shaft 172. The driving pulley 160 is a multiple pulley, the driven pulley 171 is a double pulley, and a belt 173 is wound around the driving pulley 160 and the driven pulley 171 while being tensioned by a tension roller 167. A belt 176 is wound between the driven pulley 171 and the travel input pulley 174 while being tensioned by a tension pulley 175 to form a travel drive transmission path. The driving force of the engine 48 is transmitted into the transmission device 45 via the traveling drive transmission path, and the traveling force is transmitted to the crawler type traveling devices 1 and 1 by the transmission device 45.
[0099]
Thus, the power transmission unit 110 is formed on the left side surface of the machine frame 13 by the travel drive transmission path and the threshing drive transmission path. Further, a driving belt 154 (described later) is wound around the waste beater input pulley 177, and the driving force is transmitted to the leveling conveyor 140 in the upper part of the Glen tank 30.
[0100]
Further, as shown in FIG. 3, the right end of the drive shaft 61b of the rejecting beater 61 protrudes laterally from the left side surface of the machine frame 13, and a sorting device transmission pulley 188 is fixed to the right end of the drive shaft 61b. It is installed. As shown in FIG. 16, the sorting device transmission pulley 188 is also a double pulley and transmits power to a pulley 180 that drives the rear spreader 62 via a belt 179. Also, pulleys 181 and 182 are fixedly provided at the ends of the right and left rotation shafts 28a and 31a of the first conveyor 28 and the second conveyor 31 that protrude from the right side of the machine frame 13 to the right. . Between the pulleys 181 and 182, a pulley 183 at the right end of the sprocket shaft 80 a of the whipping drive sprocket 80 of the whipping conveyor 29 is disposed, and a belt 185 is wound between these pulleys 188, 181, 182, and 183. It is turned and linked.
[0101]
Further, a carrot input pulley 184 for driving the carp 27 is arranged at the lower front part of the machine frame 13, and a belt 186 is wound between the pulley 181 of the first conveyor 28 and the carp input pulley 184 which are of the double type. Turned and driving force is transmitted. A driving force is transmitted from the pulley 182 of the second conveyor 31 to the swing link mechanism 51 of the swing main body 50 via the belt 187. Thus, the sorting device drive transmission path is formed on the right side surface of the machine frame 13. Therefore, each drive transmission path is provided separately on the left side and the right side of the machine frame 13 so that maintenance is easily performed.
[0102]
Next, the shape and support structure of the Glen tank 30 will be described. 17 is a partial rear sectional view showing the support structure of the Glen tank, FIG. 18 is a front view of the same, FIG. 19 is a side view of the left side in the traveling direction, and FIG. 21 is a partial plan sectional view showing drive transmission from the engine to the discharge auger and the discharge conveyor, and FIG. 22 is a partial plan view partial sectional view showing a power transmission configuration to the discharge conveyor or the transverse feed conveyor. As shown in FIGS. 1, 9, and 17 to 20, the Glen tank 30 is formed in a substantially square shape when viewed from the front, and the left and right ends of the Glen tank 30 are further to the right than the left and right ends of the threshing portion 18. The left and right widths of the glen tank 30 are widened to match the body width to increase the internal volume.
[0103]
Further, the lower part of the Glen tank 30 is formed in a substantially inverted triangular funnel shape as shown in the side view shown in FIGS. 1 and 19, and the lower end of the inverted triangular Glen tank 30 is along a funnel-shaped inclination. In this way, a ridge part 30a where grains are gathered, and a screw-type transverse feed conveyor 89 is pivotally supported in the left-right direction along the ridge part 30a. The transverse feed conveyor 89 conveys grains falling along the slope of the lower part of the Glen tank 30 to the right side. Further, the flange portion 30a on which the transverse feed conveyor 89 is pivotally supported is disposed between the upper covers 35 and 36 of the first rotor 21 and the second rotor 22 so that the space is effectively used. The volume of is increased.
[0104]
In addition, an upper right portion of the Glen tank 30 is formed in an inclined shape, and a rotating conveyor 41 at a storage position facing the front and rear of the upper portion of the discharge auger 40 is disposed immediately above this portion.
[0105]
Further, a discharge conveyor 88 is disposed at a lateral position above the first rotor 21 and the second rotor 22 on the lower right side of the grain tank 30 that extends to the right side from the threshing portion 18. The discharge conveyor 88 is supported by the machine frame 13, and the casing 88 a of the discharge conveyor 88 is formed by the vertical conveyor 42 of the discharge auger 40 disposed at the rear end of the machine body from the front lower part of the right side of the Glen tank 30. The discharge auger 40 and the vertical conveyor 42 are communicated with each other. Further, the screw 88b having an axial center before and after being arranged in the casing 88a is arranged from the front lower position to the side of the lower end of the vertical conveyor 42 from the transverse feed conveyor 89.
[0106]
Further, as shown in FIGS. 20 and 22, the lower right end portion of the flange portion 30 a and the upper surface of the middle portion of the casing 88 a of the discharge conveyor 88 are communicated with each other via a communication port 30 c. The grain conveyed to the right side falls from the communication port 30 c and is poured into the casing 88 a, is conveyed backward by driving the discharge conveyor 88, and is discharged from the discharge auger 40. In addition, although the discharge conveyor 88 in the lower right part of the Glen tank 30 is located on the right side of the first rotor 21 and the second rotor 22, as shown in FIG. Thus, the open / close cover 94 is not interfered.
[0107]
As shown in FIGS. 17, 18, and 20, a right-angled triangular reinforcing plate 111 is fixed to the front right side of the Glen tank 30. Similarly, a right-right triangular reinforcing plate is positioned on the right side of the rear surface of the Glen tank 30. 111 is fixed, and rigid support portions 86 and 87 are formed at the lower portions of the front and rear reinforcing plates 111 and 111. The front support portion 86 supports the outer peripheral surface of the front end portion of the discharge conveyor 88, and the rear support portion is supported. The outer peripheral surface of the discharge conveyor 88 at the lower rear part of the Glen tank 30 is pivotally supported by the support portion 87, and the pivot support portions 86 and 87 are supported on the upper part of the machine frame 13. It can be rotated around the rotation axis of the conveyor 88.
[0108]
As shown in FIGS. 17 to 19, leg frames 115 protrude downward from the left and right middle part of the front upper part of the Glen tank 30, and similarly, the left and right middle parts of the rear upper part of the Glen tank 30. A leg frame 115 protrudes downward, and the lower part of the leg frames 115 and 115 is mounted on the left end of the front part of the machine frame 13 at a position where the Glen tank 30 is rotated and rotated horizontally. To be placed.
[0109]
In addition, one end of each of the rotating arms 112 and 112 is pivotally supported on the left side of each of the front and rear reinforcing plates 111 and 11, and the other end of the rotating arms 112 and 112 and the front portion of the machine frame 13 Elevating cylinders 114 and 114 made of hydraulic cylinders are interposed between brackets 113 and 113 that are fixedly provided at the left and right middle portions of the front and rear middle portions. By extending and retracting the elevating cylinders 114 and 114, the Glen tank 30 can be rotated to the side to open the upper part of the threshing portion 18.
[0110]
Also, a bracket 91 is fixed to the lower surface of the Glen tank 30 and the bracket 91 and the left end portion of the upper cover 35 are connected by an arm 92, so that the upper cover 35 is pivoted together with the Glen tank 30 as described above. As shown in FIGS. 10 and 40, the support shaft can be rotated. As shown in FIG. 40, the upper cover 36 includes a fixed cover portion 36d on the right side with respect to the traveling direction including the communication upper portion 36a, and a rotating cover portion 36c extending to the left side from the left end of the fixed cover portion 36d. It is divided. The upper left end portion of the fixed cover portion 36d and the upper right end portion of the rotating cover portion 36c are pivotally supported via hinges 78 'and 78'. As shown in FIG. 40, the left end portion of the fixed cover portion 36d and the lower surface of the Glen tank 30 are connected via an arm or the like (not shown) so that the hinge shafts of the hinges 78 ′ and 78 ′ are centered. It is rotated upward.
[0111]
Therefore, even if the Glen tank 30 is arranged above the threshing portion 18, the Glen tank 30 is configured to be rotatable upward, so that maintenance can be performed from above the threshing portion 18. Further, the upper cover 36 and 37 are rotated in accordance with the rotation of the Glen tank 30, and the first rotor 21 and the second rotor 22 are opened, so that the internal maintenance can be easily performed. .
[0112]
The driving force of the transverse conveyor 89 in the Glen tank 30 is configured to be transmitted from the discharge conveyor 88. Even if the Glen tank 30 is rotated about the drive shaft core of the discharge conveyor 88, The power transmission path is not required to be removed. That is, as shown in FIGS. 17 and 21, the pulley 131 is fixed to the output shaft protruding rightward from the right end portion of the engine 48, and the driving force is transmitted in the gear case 125 fixed to the right side portion of the rear surface of the engine 48. The power is transmitted to the vertical conveyor 42 and the discharge conveyor 88 of the discharge auger 40 via the gear case 125, and the driving force is transmitted from the discharge conveyor 88 to the lateral feed conveyor 89.
[0113]
The gear case 125 is supported by a first transmission shaft 126 having an axial center on the left and right sides, and a second transmission shaft 129 having an axial center before and after interlocking with the first transmission shaft 126 and the bevel gears 127 and 128. A pulley 130 at the end of the first transmission shaft 126 and a pulley 291 on the output shaft of the engine 48 are linked by a belt. A pulley 134 fixed to the rear end portion of the second transmission shaft 129 is wound with a belt 134, and the belt 134 is a pulley at the rear end portion of the auger input shaft 135 pivotally supported on the lower rear portion of the casing of the vertical conveyor 42. The power of the engine 48 is transmitted to the discharge auger 40 side.
[0114]
The front end portion of the auger input shaft 135 is interlocked with the lower end portion of the drive shaft 42a of the vertical conveyor 42 via a bevel gear (not shown), and power is sequentially transmitted from the upper end portion of the vertical conveyor 42 to the rotating conveyor 41. Further, a chain 139 is wound between a sprocket 137 that is pivotally supported at the front and rear middle portions of the auger input shaft 135 and a sprocket 138 that is fixed to the rear end of the screw shaft 88c of the screw 88b of the discharge conveyor 88. 88 is driven.
[0115]
Then, as shown in FIG. 22, the drive case 119 lower part is disposed in the casing 88a in front of the screw shaft 88c of the discharge conveyor 88, and the drive case 119 is extended to the right side from the right side surface of the glen tank 30. The upper right portion of the case 119 extends to the right side surface of the glen tank 30 at the side position of the lateral feed conveyor 89 and is fixed. In the lower part of the drive case 119, an interlocking shaft 120 having left and right axial cores is supported. A bevel gear 121 is fixed to the left end portion of the interlock shaft 120, and the bevel gear 122 at the front portion of the screw shaft 88c is engaged with the bevel gear 121. Further, the right end portion of the drive shaft 89a of the transverse feed conveyor 89 is inserted into the upper portion of the drive case 119, the sprocket 132 is fixed to the end portion, and the chain 158 is wound between the sprocket 124 at the right end portion of the interlocking shaft 120. Then, the drive of the discharge conveyor 88 is transmitted to the transverse feed conveyor 89.
[0116]
Therefore, the grain stored in the Glen tank 30 can be inherited to the front part of the right discharge conveyor 88 by driving the transverse feed conveyor 89 and discharged outside the machine via the discharge auger 40.
[0117]
Further, a front portion of the screw shaft 88c is pivotally connected to the lower portion of the drive case 119 via a bearing 117, and a boss portion of the bevel gear 122 is pivotally connected via a bearing 118. The drive case 119 connects the screw shaft 88c to the bottom of the drive case 119. The workability is improved without performing work such as connecting / disconnecting the power transmission path even when the Glen tank 30 is turned.
[0118]
A screw type leveling conveyor 140 is pivotally supported in the upper part of the Glen tank 30. The leveling conveyor 140 is disposed diagonally from the left side of the rear upper part of the grain tank 30 just below the chute 85 of the cereal conveyor 29 toward the right side of the upper front part of the grain tank 30. The grains dropped from the chute 85 are first piled up on the right side of the rear part in the Glen tank 30, and when the top of the accumulated grains grows up to the leveling conveyor 140 position, the leveling conveyor 140 is driven to drive the front right side. The pile of grains is grown along the leveling conveyor 140 in a diagonal line along the leveling conveyor 140, and the interior is filled with grains.
[0119]
Further, a plurality of grain full load sensors 159, 159,... Are provided on the upper part of the grain tank 30 along the arrangement direction of the leveling conveyor 140. As shown in FIGS. 17, 19, and 20, the grain full load sensors 159, 159... Are contact-type sensors that extend the lower part of the grain full load sensor 159 to a position directly to the leveling conveyor 140. When the position of the grain piled up in the shape of a mountain grown diagonally in the Glen tank 30 along the leveling conveyor 140 is detected, and the rightmost grain full load sensor 159 detects the straw It shows that the soot is fully loaded in the Glen tank 30.
[0120]
The driving force to the leveling conveyor 140 is such that the upper part of the cylindrical vertical transmission case 141 extending in the vertical direction is inserted and fixed on the right side of the rear part of the Glen tank 30. The lower end of the L-shaped upper transmission case 142 is connected to the upper portion of the vertical transmission case 141, and the rear end portion of the drive shaft 140a of the leveling conveyor 140 is linked to the three linked shafts 151 pivotally supported on the upper portion of the upper transmission case 142. ing.
[0121]
Further, an L-shaped lower transmission case 143 in a rear view is connected to the lower portion of the vertical transmission case 141. A left and right interlocking single shaft 144 is pivotally supported at the lower portion of the lower transmission case 143, and a lower portion of the interlocking dual shaft 145 pivotally supported in the vertical transmission case 141 at the inner end portion (right end portion) of the interlocking single shaft 144 is connected to the bevel gears 146 and 147. The upper part of the interlocking two-shaft 145 is inserted into the upper transmission case 142, and the interlocking three-shaft 151 is interlocked via bevel gears 149 and 150. Further, an input pulley 148 is fixed to the left end portion of the interlocking single shaft 144 so that the driving force can be transmitted from the power transmission unit 110 via the driving belt 154.
[0122]
The right side of the lower transmission case 143 is fixed to the rear leg frame 115 via a stay 155, and the lower transmission case 143, the vertical transmission case 141, and the upper transmission case 142 are firmly fixed to the Glen tank 30 and The input pulley 148 is rotated as the tank 30 rotates.
[0123]
A driving belt 154 that transmits driving force to the input pulley 148 includes a guide pulley 152 pivotally supported via a stay 156 at the upper and lower middle portions of the rear surface of the cereal conveyor 29, and an arm 153 behind the guide pulley 152. Thus, it is wound around a tension pulley 157 pivotally supported so as to be pivotable up and down. The tension pulley 157 is urged upward by a spring (not shown), for example, a waste beater input pulley 177 on a drive transmission path to the threshing portion in the power transmission unit 110, the guide pulley 152, and the tension pulley 157 Thus, the drive belt 154 is wound in an inverted triangular shape.
[0124]
Therefore, when the Glen tank 30 is rotated to the horizontal work position, the input pulley 148 enters between the guide pulley 152 and the tension pulley 157, and the drive pulley 154 is positioned below the input pulley 148 in the meantime. The half part is wound and the driving force is transmitted, and the leveling conveyor 140 is driven along with the driving of the threshing unit 18 during the harvesting operation, so that the grains are fully loaded in the glen tank 30 formed widely.
[0125]
Further, since the lower half of the input pulley 148 is only wound around the drive belt 154, the input pulley 148 is pulled out from the upper side of the drive belt 154 without being caught when the Glen tank 30 is rotated to the side. Thus, work such as removing the drive belt 154 is unnecessary, and workability is improved.
[0126]
Thus, the machine frame 13 with excellent maintainability is placed above the crawler type traveling device 1 with improved running stability, and the threshing section 18 is compact and has excellent threshing performance in the machine frame 13. Is stored in the front of the machine body, and the cut cocoon harvested from the reaping section 8 is transported to the threshing section 18 and smoothly discharged to the outside of the machine. The sorting device 19 reliably sorts the first thing and puts it in the grain tank 30 formed above the threshing portion 18 in accordance with the left and right width of the machine body without damaging the most thing, and continues the harvesting operation. As a general-purpose combine that can efficiently harvest in large-scale fields, shorten the work time, reliably harvest, and select and store without waste is constructed. is there.
[0127]
【The invention's effect】
Since the present invention is configured as described above, the following effects can be obtained.
As in claim 1, the sorting device (19) is placed on the traveling device (1), and a threshing portion (18) having a left and right rotor is disposed above the sorting device (19), and above the threshing portion (18). In a general-purpose combine having a grain tank (30), the lower part of the grain tank (30) is formed in an inverted triangular funnel shape when viewed from the side, and a transverse feed conveyor (89) is installed horizontally on the funnel-shaped lower part The transverse feed conveyor (89) is disposed between the upper portions of the rotors of the threshing section (18) disposed at the front and rear, and an opening is provided below the lateral end of the lateral feed conveyor (89), The opening is below the opening It extends in the front-rear direction and communicates with the discharge conveyor (88) connected to the discharge auger (40), and the Glen tank (30) rotates in the vertical direction around the position of the discharge conveyor (88). By supporting it as possible, the internal volume can be made sufficiently large and the continuous operation of the harvesting operation can be performed even as a configuration with a limited height in which the Glen tank is arranged above the threshing portion. I have to.
[0128]
In addition, the lower part of the Glen tank is formed in an inverted triangular funnel shape when viewed from the side, and a transverse feed conveyor is installed horizontally on the lower part of the funnel shape. Can be sent and collected in the horizontal direction, and it is easy to discharge out of the glen tank.
[0129]
Moreover, since the transverse feed conveyor position at the lower part of the Glen tank formed in a funnel shape is arranged between the upper and lower rotors, the volume of the Glen tank can be increased by effectively using the space, and the harvesting work The continuity of can be improved.
[0130]
In addition, since an opening is provided below the end of the transverse feed conveyor and communicated with a discharge conveyor that extends back and forth below the opening and is connected to the discharge auger, the grains in the grain tank are horizontally fed. It is collected on the left and right sides by the conveyor, and the collected grains can be easily transferred to the discharge conveyor and discharged from the discharge auger.
[0131]
In addition, by supporting the Glen tank so that it can be turned up and down around the position of the discharge conveyor that extends back and forth, the Glen tank can be easily moved upward without removing the grain discharging structure. Since it can be rotated and the threshing portion below the Glen tank can be maintained, workability is good.
[0132]
As in claim 2, a drive case (119) is fixed to the side of the glen tank at the lateral position of the transverse feed conveyor, and the lower portion of the drive case (119) is pivotally supported on the discharge conveyor (88). Since the driving force of the discharge conveyor (88) is taken into the drive case (119) and transmitted to the transverse feed conveyor (89), the transverse feed conveyor is placed in the lower part of the Glen tank rotated around the discharge conveyor. However, the work of removing the drive transmission path to the cross feed conveyor in the middle is unnecessary, the Glen tank can be easily rotated upward, and the threshing section below the Glen tank The workability is good because maintenance can be performed.
[0133]
According to claim 3, the grain screened by the sorting device is provided so as to be able to be fed from the upper part of the left and right sides of the grain tank via the pulverized conveyor, Since the leveling conveyor (140) that extends in the opposite direction from the left and right sides of the grain tank is provided on the left and right sides of the grain tank, the grain is introduced into the left and right sides of the wide grain tank by the cereal conveyor Even if grain is deposited on the side in the Glen tank, the upper part of the grain deposited on the leveling conveyor (140) provided on the top of the Glen tank is sent to the opposite side. Thus, grains can be stored in the Glen tank as much as possible without gaps, the volume of the Glen tank can be used effectively, and the continuity of the harvesting operation is improved.
[0134]
As in claim 4, a transmission case of the leveling conveyor (140) is provided along the side surface of the Glen tank, an input pulley is pivotally supported under the transmission case, and the Glen tank is rotated to the working position. Since the input pulley (148) at the time is in contact with the upper surface of the drive belt (154) that transmits driving to the threshing portion and wound so as to be able to transmit power, the harvesting operation is interlocked with the driving of the threshing portion. The conveyor at the top of the Glen tank can be driven while it is being performed.
Even if the harvesting operation is stopped and the Glen tank is rotated upward for maintenance, the input pulley (148) is rotated along with the Glen tank (30). 148) contacts and is wound without being interfered with the upper part of the drive belt (154) that has been wound, so that the work of removing the belt of the power transmission path is unnecessary, and the transition to the maintenance work is extremely easy. Workability is improved.
[Brief description of the drawings]
FIG. 1 is an overall side view and partial cross-sectional view of a general-purpose combiner.
FIG. 2 is a side sectional view of a threshing unit and a sorting device.
FIG. 3 is a plan sectional view of a threshing portion.
FIG. 4 is a side sectional view of a threshing portion.
FIG. 5 is a side sectional view of the same.
FIG. 6 is a side sectional view showing a maintenance configuration of a beater in the front part of the machine frame.
FIG. 7 is a plan sectional view of another configuration of the second rotor that discharges the waste from the threshing portion.
FIG. 8 is a partial cross-sectional side view of a whipping conveyor.
FIG. 9 is a plan view of the machine frame.
FIG. 10 is a partial cross-sectional view of a front view of a rotational configuration of a threshing portion door that covers the right end portion of a rotor.
FIG. 11 is a right side view of the traveling direction.
FIG. 12 is a right side view in the traveling direction with the threshing section door opened.
FIG. 13 is a left side view of the cutting unit in the traveling direction.
FIG. 14 is a front view showing a pulley position of an engine for transmitting power.
FIG. 15 is a side view showing a power transmission path to a threshing unit and a traveling device.
FIG. 16 is a side view showing a power transmission path to the sorting device.
FIG. 17 is a partial cross-sectional view of the rear view showing the support structure of the Glen tank.
FIG. 18 is a front view of the same.
FIG. 19 is a side view on the left side in the same direction of travel.
FIG. 20 is a partial cross-sectional view of a plan view of a Glen tank.
FIG. 21 is a partial plan sectional view showing drive transmission from an engine to a discharge auger and a discharge conveyor.
FIG. 22 is a partial cross-sectional view of a partial plan view showing a power transmission configuration to a discharge conveyor or a transverse feed conveyor.
FIG. 23 is a plan view of the cabin.
FIG. 24 is a side view of the cabin.
FIG. 25 is a front view of the cabin.
FIG. 26 is a side view of the crawler type traveling device.
FIG. 27 is a front sectional view of an idler wheel.
FIG. 28 is a partial cross-sectional view of a plan view showing a support configuration of a crawler tension ring and the like.
FIG. 29 is a side sectional view showing an intake configuration of the engine room.
FIG. 30 is a front sectional view of the same.
FIG. 31 is a plan sectional view of the same.
FIG. 32 is a right side view of the cutting part.
FIG. 33 is a partial front view of a cutting part.
FIG. 34 is a partial development view of a cutting part.
FIG. 35 is a side view of a connection configuration between the platform of the cutting unit and the feeder house.
FIG. 36 is a partial rear view of the platform connection configuration.
FIG. 37 is a partial side cross-sectional view of the same.
FIG. 38 is a partial bottom view of the connection configuration at the bottom of the platform.
FIG. 39 is a partial plan view of the connection configuration at the top of the platform.
FIG. 40 is a front view showing a support configuration of the upper cover.
[Explanation of symbols]
1 Traveling device
13 Machine frame
18 Threshing department
19 Sorting device
21 First rotor
22 Second rotor
29 Grain conveyor
30 Glentank
40 discharge auger
88 Discharge conveyor
89 Transverse conveyor
119 Drive case
140 Leveling conveyor
141 Vertical transmission case
142 Upper transmission case
143 Lower transmission case
148 Input pulley
154 Drive belt

Claims (4)

The sorting device (19) is placed on the traveling device (1), a threshing portion (18) having a left and right rotor is disposed above the sorting device (19), and a glen tank (30) is disposed above the threshing portion (18). In the arranged general-purpose combiner, the lower part of the Glen tank (30) is formed in an inverted triangular funnel shape in a side view, and a transverse feed conveyor (89) is installed horizontally on the lower part of the funnel shape. (89), placed between the upper portion of the rotor of the threshing unit arranged in the longitudinal (18), the transverse feed conveyor (89) an opening below the lateral direction of the terminal portion is provided, the opening is below the opening The glen tank (30) is rotated in the vertical direction around the position of the discharge conveyor (88). Characterized by support for movement Use combine.   The general-purpose combine according to claim 1, wherein a drive case for driving the lateral feed conveyor (89) from the discharge conveyor (88) on the side surface of the glen tank (30) at a lateral position of the lateral feed conveyor (89) ( 119) is fixed, the drive case (119) is pivotally supported about the screw shaft (88c) of the discharge conveyor (88), and the Glen tank (30) is rotated in the vertical direction. The driving force of the screw shaft (88c) of the discharge conveyor (88) is taken into the driving case (119) and the driving force is transmitted to the lateral feed conveyor (89) without breaking the power transmission path in the middle. A general-purpose combine characterized by that. Oite the universal combine of claim 1, wherein, provided to be turned from the top of the sorting device (19) grain tank (30) via a AgeKoku conveyor (29) the sorted grain in a left and right side portions, A leveling conveyor (140) extending diagonally from the left and right sides of the upper part of the grain tank (30) is provided at a position immediately before the input part of the cereal conveyor (29). General-purpose combine characterized by that.   The general purpose combine according to claim 3, wherein a transmission case (141, 142, 143) for transmitting a driving force to the end of the leveling conveyor (140) is arranged vertically along the side surface of the Glen tank (30). When the input pulley (148) is pivotally supported on the lower part of the transmission case (141, 142, 143) and the glen tank (30) is rotated downward to the working position, the input pulley (148) is moved to the threshing portion ( 18) A general-purpose combine that is wound so as to be able to transmit power while abutting on the upper surface of a drive belt (154) that transmits a driving force.

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